Fundamentals of Radiative Transfer / Chapter 1: |
The Electromagnetic Spectrum; Elementary Properties of Radiation / 1.1: |
Radiative Flux / 1.2: |
The Specific Intensity and Its Moments / 1.3: |
Radiative Transfer / 1.4: |
Thermal Radiation / 1.5: |
The Einstein Coefficients / 1.6: |
Scattering Effects; Random Walks / 1.7: |
Radiative Diffusion / 1.8: |
Basic Theory of Radiation Fields / Chapter 2: |
Review of Maxwell's Equations / 2.1: |
Plane Electromagnetic Waves / 2.2: |
The Radiation Spectrum / 2.3: |
Polarization and Stokes Parameters 62 / 2.4: |
Electromagnetic Potentials / 2.5: |
Applicability of Transfer Theory and the Geometrical Optics Limit / 2.6: |
Radiation from Moving Charges / Chapter 3: |
Retarded Potentials of Single Moving Charges: The LiTnard-Wiechart Potentials / 3.1: |
The Velocity and Radiation Fields / 3.2: |
Radiation from Nonrelativistic Systems of Particles / 3.3: |
Thomson Scattering (Electron Scattering) / 3.4: |
Radiation Reaction / 3.5: |
Radiation from Harmonically Bound Particles / 3.6: |
Relativistic Covariance and Kinematics / Chapter 4: |
Review of Lorentz Transformations / 4.1: |
Four-Vectors / 4.2: |
Tensor Analysis / 4.3: |
Covariance of Electromagnetic Phenomena / 4.4: |
A Physical Understanding of Field Transformations 129 / 4.5: |
Fields of a Uniformly Moving Charge / 4.6: |
Relativistic Mechanics and the Lorentz Four-Force / 4.7: |
Emission from Relativistic Particles / 4.8: |
Invariant Phase Volumes and Specific Intensity / 4.9: |
Bremsstrahlung / Chapter 5: |
Emission from Single-Speed Electrons / 5.1: |
Thermal Bremsstrahlung Emission / 5.2: |
Thermal Bremsstrahlung (Free-Free) Absorption / 5.3: |
Relativistic Bremsstrahlung / 5.4: |
Synchrotron Radiation / Chapter 6: |
Total Emitted Power / 6.1: |
Spectrum of Synchrotron Radiation: A Qualitative Discussion / 6.2: |
Spectral Index for Power-Law Electron Distribution / 6.3: |
Spectrum and Polarization of Synchrotron Radiation: A Detailed Discussion / 6.4: |
Polarization of Synchrotron Radiation / 6.5: |
Transition from Cyclotron to Synchrotron Emission / 6.6: |
Distinction between Received and Emitted Power / 6.7: |
Synchrotron Self-Absorption / 6.8: |
The Impossibility of a Synchrotron Maser in Vacuum / 6.9: |
Compton Scattering / Chapter 7: |
Cross Section and Energy Transfer for the Fundamental Process / 7.1: |
Inverse Compton Power for Single Scattering / 7.2: |
Inverse Compton Spectra for Single Scattering / 7.3: |
Energy Transfer for Repeated Scatterings in a Finite, Thermal Medium: The Compton Y Parameter / 7.4: |
Inverse Compton Spectra and Power for Repeated Scatterings by Relativistic Electrons of Small Optical Depth / 7.5: |
Repeated Scatterings by Nonrelativistic Electrons: The Kompaneets Equation / 7.6: |
Spectral Regimes for Repeated Scattering by Nonrelativistic Electrons / 7.7: |
Plasma Effects / Chapter 8: |
Dispersion in Cold, Isotropic Plasma / 8.1: |
Propagation Along a Magnetic Field; Faraday Rotation / 8.2: |
Plasma Effects in High-Energy Emission Processes / 8.3: |
Atomic Structure / Chapter 9: |
A Review of the Schr÷dinger Equation / 9.1: |
One Electron in a Central Field / 9.2: |
Many-Electron Systems / 9.3: |
Perturbations, Level Splittings, and Term Diagrams / 9.4: |
Thermal Distribution of Energy Levels and Ionization / 9.5: |
Radiative Transitions / Chapter 10: |
Semi-Classical Theory of Radiative Transitions / 10.1: |
The Dipole Approximation / 10.2: |
Einstein Coeffic / 10.3: |
Fundamentals of Radiative Transfer / Chapter 1: |
The Electromagnetic Spectrum; Elementary Properties of Radiation / 1.1: |
Radiative Flux / 1.2: |
The Specific Intensity and Its Moments / 1.3: |
Radiative Transfer / 1.4: |
Thermal Radiation / 1.5: |