目录 Preface Acknowledgements Author biography 1 Introduction and overview 1.1 The free-electron laser 1.2 Classical stimulated emission 1.3 Electron bunching 1.4 FEL equations of motion References 2 The classical limit 2.1 Emission and absorption 2.2 Compton recoil 2.3 Wavepacket spreading References 3 Electron beam dynamics 3.1 Phase space and emittance 3.1.1 Beam envelope equation 3.2 Focusing properties of the undulator 3.3 Matching into the FEL Reference 4 Undulator trajectories 4.1 Transverse motion 4.2 Longitudinal motion 5 Spontaneous emission 5.1 Spectral lineshape 5.2 Spontaneous power (weak undulator fields) 5.3 Spontaneous power (strong undulator fields) References 6 Effect of the optical field on electron motion 6.1 The Lorentz equation 6.2 The FEL pendulum equation References 7 Effect of electron motio~ on the optical field 7.1 The wave equation 7.2 Transverse currents 7.3 The FEL wave equation 7.4 Energy conservation References 8 Transverse modes in the equations of motion 8.1 Superposition of transverse modes 8.2 The mode evolution equation 8.3 The multimode pendulum equation 8.4 The filling factor References 9 Small-signal gain--first derivation 9.1 Gain from energy conservation 9.2 Gain-spread theorem 9.3 Approximate solution of the FEL equations 9.4 Gouy phase shift References
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