Insertion Devices for Synchrotron Radiation and Free Electron Laser

    This book describes the basic properties of charged beam transport and the theory of accelerators with radiative damping. The characteristics of the third generation synchrotron radiation sources are analyzed and compared to those of the first and second generations. This is followed by the conceptual and technological problems associated with the discovery of the fourth generation sources. Within this framework, the role played by free electron laser devices is discussed and relevant theoretical and technological aspects of storage-ring and Linac-based sources are analyzed.

Preface
Foreword
1 An Introduction to the Theory of Charged Particle Transport
1.1 Summary of the properties of relativistic particles
1.2 Introducing the basic elements of a transport system
1.2.1 Dipole or bending magnet
1.2.2 The quadrupole magnet
1.3 Transport system and phase-space evolution
1.4 The synchrotron magnet and the Dispersion function
1.5 Transverse motion coupling and sextupole magnets
1.6 Periodicity conditions on circular transport and motion stability conditions
1.7 Chromaticity,resonances and concluding remarks
1.8 Problems
A Bending magnets and magnetic lenses
B Treatment of charged beam transport using Lie algebra
2 Generalities on Synchrotron Radiation
2.1 Introduction
2.2 Lienard-Wiechert potentials
2.3 Spectral properties of the synchrotron radiation
2.4 Damping and beam equilibrium conditions
2.5 The Fokker-Planck treatment of the longitudinal equilibrium proble
2.6 Synchrotron radiation from magneic undulators
2.7 Comcluding remarks
2.8 Problems
3 Generalities on Free Electron Lasers
4 Optical Systems in the Geometrical and Wave Optics Framework
5 Wigner Distribution and Synchrotron Radiation Sources
6 Synchrotron Radiation Sources, Insertion Devices and Beam Current Limitations
7 Constructing and Measuring Insertion Devices
8 Free Electron Lasers as Insertion Devices
9 Synchrotron Radiation Beam Lines: X-Ray Optics
Index