Linked e-resources
Details
Table of Contents
Intro; Preface; References; Preface to the Second Edition; References; Preface to the First Edition; References; Acknowledgments; Contents; Chapter 1: Introduction; 1.1 Principles of Operation; 1.2 Quantum Mechanical Effects; 1.3 Experiments and Applications; 1.4 Discussion; References; Chapter 2: The Wiggler Field and Electron Dynamics; 2.1 Helical Wiggler Configurations; 2.1.1 Idealized One-Dimensional Trajectories; 2.1.2 Steady-State Trajectories; 2.1.3 Stability of the Steady-State Trajectories; 2.1.4 Negative-Mass Trajectories; 2.1.5 General Integration of the Orbit Equations
2.1.6 Trajectories in a Realizable Helical Wiggler2.1.7 Steady-State Trajectories; 2.1.8 Stability of the Steady-State Trajectories; 2.1.9 Negative-Mass Trajectories; 2.1.10 Generalized Trajectories: Larmor and Betatron Oscillations; 2.2 Planar Wiggler Configurations; 2.2.1 Idealized One-Dimensional Trajectories; 2.2.2 Quasi-Steady-State Trajectories; 2.2.3 Negative-Mass Trajectories; 2.2.4 Trajectories in Realizable Planar Wigglers; 2.2.5 Gradient Drifts Due to an Axial Magnetic Field; 2.2.6 Betatron Oscillations; 2.2.7 The Effect of Parabolic Pole Faces; 2.3 Tapered Wiggler Configurations
2.3.1 The Idealized One-Dimensional Limit2.3.2 The Realizable Three-Dimensional Formulation; 2.3.3 Planar Wiggler Geometries; References; Chapter 3: Incoherent Undulator Radiation; 3.1 Test Particle Formulation; 3.2 The Cold Beam Regime; 3.3 The Temperature-Dominated Regime; References; Chapter 4: Coherent Emission: Linear Theory; 4.1 Phase Space Dynamics and the Pendulum Equation; 4.2 Linear Stability in the Idealized Limit; 4.2.1 Helical Wiggler Configurations; 4.2.1.1 The Source Currents; 4.2.1.2 The Pierce Parameter; 4.2.1.3 The Low-Gain Regime; 4.2.1.4 The High-Gain Regime
The General Dispersion EquationThe Stability of Beam-Plasma Modes; A Reduced Form of the Dispersion Equation; Dispersive Effects on the Interaction; The Compton and Raman Regimes; The Transition Between the Compton and Raman Regimes; 4.2.1.5 The Effect of an Axial Magnetic Field; The Case of a Weak Magnetic Field; The Case of a Strong Magnetic Field; 4.2.1.6 Thermal Effects on the Instability; 4.2.2 Planar Wiggler Configurations; 4.2.2.1 The Source Currents; 4.2.2.2 The Pierce Parameter and the JJ-Factor; 4.2.2.3 The Low-Gain Regime; 4.2.2.4 The High-Gain Regime; The Compton and Raman Regimes
4.2.2.5 Thermal Effects on the Instability4.2.2.6 The Effect of an Axial Magnetic Field; 4.3 Linear Stability in Three Dimensions; 4.3.1 Waveguide Mode Analysis; 4.3.1.1 The Low-Gain Regime; 4.3.1.2 The High-Gain Regime; The Source Currents; The Dispersion Equation; Numerical Solution of the Dispersion Equation; Comparison with Experiment; 4.3.2 Optical Mode Analysis; 4.3.2.1 Helical Wiggler Configurations; The Electron Trajectories; The Dispersion Equation; The Idealized, One-Dimensional Limit; Ming Xie Parameterization; 4.3.2.2 Planar Wiggler Configurations; The Electron Trajectories
2.1.6 Trajectories in a Realizable Helical Wiggler2.1.7 Steady-State Trajectories; 2.1.8 Stability of the Steady-State Trajectories; 2.1.9 Negative-Mass Trajectories; 2.1.10 Generalized Trajectories: Larmor and Betatron Oscillations; 2.2 Planar Wiggler Configurations; 2.2.1 Idealized One-Dimensional Trajectories; 2.2.2 Quasi-Steady-State Trajectories; 2.2.3 Negative-Mass Trajectories; 2.2.4 Trajectories in Realizable Planar Wigglers; 2.2.5 Gradient Drifts Due to an Axial Magnetic Field; 2.2.6 Betatron Oscillations; 2.2.7 The Effect of Parabolic Pole Faces; 2.3 Tapered Wiggler Configurations
2.3.1 The Idealized One-Dimensional Limit2.3.2 The Realizable Three-Dimensional Formulation; 2.3.3 Planar Wiggler Geometries; References; Chapter 3: Incoherent Undulator Radiation; 3.1 Test Particle Formulation; 3.2 The Cold Beam Regime; 3.3 The Temperature-Dominated Regime; References; Chapter 4: Coherent Emission: Linear Theory; 4.1 Phase Space Dynamics and the Pendulum Equation; 4.2 Linear Stability in the Idealized Limit; 4.2.1 Helical Wiggler Configurations; 4.2.1.1 The Source Currents; 4.2.1.2 The Pierce Parameter; 4.2.1.3 The Low-Gain Regime; 4.2.1.4 The High-Gain Regime
The General Dispersion EquationThe Stability of Beam-Plasma Modes; A Reduced Form of the Dispersion Equation; Dispersive Effects on the Interaction; The Compton and Raman Regimes; The Transition Between the Compton and Raman Regimes; 4.2.1.5 The Effect of an Axial Magnetic Field; The Case of a Weak Magnetic Field; The Case of a Strong Magnetic Field; 4.2.1.6 Thermal Effects on the Instability; 4.2.2 Planar Wiggler Configurations; 4.2.2.1 The Source Currents; 4.2.2.2 The Pierce Parameter and the JJ-Factor; 4.2.2.3 The Low-Gain Regime; 4.2.2.4 The High-Gain Regime; The Compton and Raman Regimes
4.2.2.5 Thermal Effects on the Instability4.2.2.6 The Effect of an Axial Magnetic Field; 4.3 Linear Stability in Three Dimensions; 4.3.1 Waveguide Mode Analysis; 4.3.1.1 The Low-Gain Regime; 4.3.1.2 The High-Gain Regime; The Source Currents; The Dispersion Equation; Numerical Solution of the Dispersion Equation; Comparison with Experiment; 4.3.2 Optical Mode Analysis; 4.3.2.1 Helical Wiggler Configurations; The Electron Trajectories; The Dispersion Equation; The Idealized, One-Dimensional Limit; Ming Xie Parameterization; 4.3.2.2 Planar Wiggler Configurations; The Electron Trajectories