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by D. P. Craig,T. Thirunamachandran
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ISBN: 0486402142 Dover Publications Price: $18.95 |
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Of equal value to students and experts, this self-contained, systematic introduction features formal derivations of the quantized field matrix elements for numerous laser-molecule interaction effects: one- and two-photon absorption and emission, Rayleigh and Raman scattering, linear and nonlinear optical processes, the Lamb shift, and much more.
Table of Contents for Molecular Quantum Electrodynamics
| Preface | |||||||
| Chapter 1 Introduction | |||||||
| 1.1 The Nature of Electrodynamics | |||||||
| 1.2 Maxwell's Equations for the Macroscopic Field | |||||||
| 1.3 The Microscopic Field Equations | |||||||
| 1.4 The Electromagnetic Potentials | |||||||
| 1.5 Lorentz and Coulomb Gauges | |||||||
| 1.6 Quantum Mechanics of a System of Charges | |||||||
| 1.7 "Classical Electrodynamics, Quantum Electrodynamics and Semiclassical Electrodynamics" | |||||||
| Chapter 2 The Electromagnetic Field in Free Space | |||||||
| 2.1 The Classical Electromagnetic Field in a Region Free of Sources | |||||||
| 2.2 "Electromagnetic Waves in a "Box" | |||||||
| 2.3 "Linear, Elliptical and Circular Polarization" | |||||||
| 2.4 Lagrangian and Hamiltonian for the Free Field | |||||||
| 2.5 The Electromagnetic Field as a Sum of Mode Oscillators | |||||||
| 2.6 Quantization of the Harmonic Oscillator | |||||||
| 2.7 A System of Oscillators | |||||||
| 2.8 Quantization of the Free Field | |||||||
| 2.9 Summations Over Wave Vectors and Polarizations | |||||||
| 2.10 Uncertainty Relations. Fluctuations of the Vacuum Fields | |||||||
| 2.11 Coherent States | |||||||
| 2.12 Coherent States as States of Minimum Uncertainty | |||||||
| 2.13 Thermal and Chaotic States | |||||||
| Chapter 3 Particles and Fields | |||||||
| 3.1 Transverse and Longitudinal d-dyadics | |||||||
| 3.2 Molecules and Fields: Lagrangian Formulation | |||||||
| 3.3 Molecules and Fields: Hamiltonian Formulation | |||||||
| 3.4 Instantaneous and Retarded Interactions | |||||||
| 3.5 Quantization of the Coupled System | |||||||
| 3.6 The Electric Dipole Approximation | |||||||
| 3.7 A Higher Approximation | |||||||
| Chapter 4 One-Photon Absorption and Emission | |||||||
| 4.1 Introduction | |||||||
| 4.2 Time Development in a Two-State Model | |||||||
| 4.3 Time Evolution and Time-Dependent Perturbations | |||||||
| 4.4 An Application: the Steady Perturbation | |||||||
| 4.5 Time-Dependent Perturbations Treated by Dirac's Method | |||||||
| 4.6 A Discrete State Coupled to a Continuum. The Fermi Golden Rule | |||||||
| 4.7 One-Photon Absorption | |||||||
| 4.8 The Einstein B-coefficient | |||||||
| 4.9 Relaxation of the Number State Assumption | |||||||
| 4.10 The Sum Rule for Oscillator Strengths | |||||||
| 4.11 Spontaneous Emission and the Einstein A-coefficient | |||||||
| 4.12 Stimulated (Induced) Emission | |||||||
| 4.13 Magnetic Dipole and Electric Quadrupole Transitions | |||||||
| 4.13A Magnetic dipole allowed transitions | |||||||
| 4.13B Electric quadrupole allowed transitions | |||||||
| 4.13C Interference effects | |||||||
| 4.14 Equivalence of Matrix Elements in Minimal Coupling and Multipolar Formalisms | |||||||
| 4.15 Calculation of the 2p ? 1s Transition in Hydrogen with the Complete Vector Potential | |||||||
| 4.16 Calculation of the Photoionization Rate of Hydrogen with the Complete Vector Potential | |||||||
| Chapter 5 Two-Photon Absorption Emission | |||||||
| 5.1 Introduction | |||||||
| 5.2 Two-Photon Absorption From a Single Beam | |||||||
| 5.3 Two-Photon Absorption From Two | |||||||
| 5.4 Selection Rules for Two-Photon Absorption and Emission | |||||||
| 5.5 Doppler-Free Spectroscopy | |||||||
| 5.6 Two-Photon Emission | |||||||
| 5.7 Two-Photon Stimulated Emission | |||||||
| 5.8 Equivalence of Two-Photo Matrix Elements | |||||||
| Chapter 6 Rayleigh and Raman Scattering | |||||||
| 6.1 Two-Photo Scattering. The Kramers-Heisenberg Dispersion Formula | |||||||
| 6.2 Rayleigh Scattering | |||||||
| 6.3 Rayleigh Scattering by Randomly Oriented Molecules | |||||||
| 6.4 Raman Scattering | |||||||
| 6.5 Raman Intensities | |||||||
| 6.6 Stimulated and Inverse Raman Scattering | |||||||
| Chapter 7 Interactions Between Molecules | |||||||
| 7.1 Introduction | |||||||
| 7.2 The Resonance Interaction in Electric Dipole Approximation | |||||||
| 7.3 Resonance Interaction in the Minimal Coupling Method | |||||||
| 7.4 The Dispersion Energy | |||||||
| 7.5 The Wave-zone Limit: Casimir-Polder Potential | |||||||
| 7.6 The Near-zone Limit: London Potential | |||||||
| 7.7 Dispersion Energy. The Complete Potential | |||||||
| 7.8 Interaction Between Permanent Dipoles | |||||||
| 7.9 Chiral Discrimination. The Resonance Interaction Between Chiral Systems | |||||||
| 7.10 Chiral Discrimination. Discriminatory Dispersion Interactions in the Wave-zone | |||||||
| 7.11 Discriminatory Dispersion Interactions in the Near-zone | |||||||
| 7.12 Intermolecular Interactions in a Radiation Field | |||||||
| 7.13 Radiation-induced Chiral Discrimination | |||||||
| Chapter 8 Optical Activity | |||||||
| 8.1 Introduction | |||||||
| 8.2 Circular Dichroism | |||||||
| 8.3 Inclusion of Electric Quadrupole Interactions | |||||||
| 8.4 A Two-State Model for Optical Rotation | |||||||
| 8.5 Calculation of the Matrix Element for Optical Rotation | |||||||
| 8.6 Differential Rayleigh and Raman Scattering of Circularly Polarized Light | |||||||
| 8.7 Quadrupole Contributions to Differential Scattering | |||||||
| 8.8 Magnetic Circular Dichroism | |||||||
| 8.9 The Two-Group Model for Circular Dichroism | |||||||
| 8.10 The Two-Group Model for Optical Rotation | |||||||
| 8.11 Induced Circular Dichroism | |||||||
| Chapter 9 Non-Linear Optical Processes | |||||||
| 9.1 Harmonic Generation | |||||||
| 9.2 Static Field-Induced Second Harmonic Generation | |||||||
| 9.3 Hyper-Raman Scattering | |||||||
| 9.4 Selection Rules for Hyper-Raman Scattering | |||||||
| 9.5 Laser-Induced Circular Dichroism | |||||||
| 9.6 "The Field "Dressing" Approach to Laser-Induced Circular Dichroism" | |||||||
| 9.7 Laser-Induced Optical Rotation | |||||||
| 9.8 Laser-Induced Resonance Fluorescence | |||||||
| 9.9 The Optical Kerr Effect | |||||||
| 9.10 Coherent anti-Stokes Raman Scattering (CARS) | |||||||
| Chapter 10 Transformations and Multipolar Electrodynamics | |||||||
| 10.1 Introduction | |||||||
| 10.2 The Electric Polarization Field | |||||||
| 10.3 The Magnetization Field | |||||||
| 10.4 Partitioning of the Current Density | |||||||
| 10.5 The Multipolar Lagrangian | |||||||
| 10.6 Atomic Field Equations | |||||||
| 10.7 The Multipolar Hamiltonian | |||||||
| 10.8 Cancellation of the Intermolecular Interactions in the Multipolar Hamilt | |||||||
| 10.9 Canonical Transformations | |||||||
| 10.10 The Multipolar Hamiltonian by the Canonical Transformation Method | |||||||
| 10.11 Equivalence of Matrix Elements | |||||||
| 10.12 Canonical Transformation and Perturbation Theory | |||||||
| 10.13 The Röntgen Current | |||||||
| Chapter 11 Self-Interactions | |||||||
| 11.1 Introduction | |||||||
| 11.2 Static Self-Energy | |||||||
| 11.3 The Transverse Self-Energy of the Free Electron | |||||||
| 11.4 Mass Renormalization by Canonical Transformation | |||||||
| 11.5 Mass Renormalization in the Multipolar Formalism | |||||||
| 11.6 The Lamb Shift | |||||||
| 11.7 Lamb Shift Calculated by Canonical Transformation | |||||||
| 11.8 Lamb Shift via the Multipolar Hamiltonian | |||||||
| Appendix 1 Proofs of Three Identities for Non-commuting Operators | |||||||
| Appendix 2 Rotational Averaging of Tensors | |||||||
| Appendix 3 Principal Equations Expressed in Gaussian Units | |||||||
| Index | |||||||