Charged beam dynamics, particle accelerators and free electron lasers /

Charged beam dynamics, particle accelerators and free electron lasers /

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Bibliographic Details
Author / Creator:Dattoli, G., author.
Imprint:Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2017]
Description:1 online resource (various pagings) : illustrations (some color).
Language:English
Series:[IOP release 4]
IOP plasma physics series
IOP expanding physics, 2053-2563
IOP (Series). Release 4.
IOP plasma physics series.
IOP expanding physics.
Subject:
Beam dynamics.
Particle accelerators.
Free electron lasers.
Beam dynamics.
Free electron lasers.
Particle accelerators.
Format: E-Resource Book
URL for this record:http://pi.lib.uchicago.edu/1001/cat/bib/11432362
Hidden Bibliographic Details
Other authors / contributors:Doria, Andrea (Physicist), author.
Sabia, Elio, author.
Artioli, Marcello, 1970- author.
Institute of Physics (Great Britain), publisher.
ISBN:9780750312394
9780750312417
9780750312400
Notes:"Version: 20170901"--Title page verso.
Includes bibliographical references.
Also available in print.
System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.
The authors are researchers at the ENEA-Frascati Research Center in Italy. Giuseppe Dattoli has been involved in many research projects, including high energy accelerators, FELs, and applied mathematics networks since 1979, receiving the FEL Prize Award for his outstanding achievements in the field. Andrea Doria's research interests are Cerenkov based FELs, compact FEL sources in the millimetre and far IR regions, and coherence and correlation effects on FEL power output. Elio Sabia has been involved in theoretical problems connected with particle dynamics in high-energy electron accelerators driven FELs. Marcello Artioli works on control systems and computer science.
Title from PDF title page (viewed on October 26, 2017).
Summary:Charged Beam Dynamics, Particle Accelerators and Free Electron Lasers' summarises different topics in the field of accelerators and of Free Electron Laser (FEL) devices. It explains how to design both an FEL device and the accelerator providing the driving beam. Covering both theoretical and experimental aspects, this book allows researchers to attempt a first design of an FEL device.
Other form:Print version: 9780750312400
Standard no.:10.1088/978-0-7503-1239-4
Table of Contents:
  • Preface
  • 1. Charged particle dynamics and beam transport optics
  • 1.1. Introduction
  • 1.2. A planar diode and the Child-Langmuir law
  • 1.3. The klystron concept
  • 1.4. Charged particle motion in combined electric and magnetic fields (the non-relativistic case)
  • 1.5. Charged particle motion in combined electric and magnetic fields (the relativistic case)
  • 1.6. Hamiltonian theory of charged particle motion
  • 1.7. Beam transport, Liouville theorem and beam emittance
  • 1.8. The Vlasov equation and beam transport
  • 1.9. The Vlasov equation and the method of momenta
  • 1.10. Emittance, normalized emittance and beam brightness
  • 1.11. Beam transport elements, dipole, quadrupoles ...
  • 1.12. Beam transport and matrix formalism
  • 1.13. Composed transport devices and the matrix formalism
  • 1.14. Beam transport : a few pragmatic remarks
  • 1.15. Complements and exercises
  • 2. Linear accelerators
  • 2.1. Introduction
  • 2.2. Accelerating cavities, shunt impedance and quality factor
  • 2.3. Electromagnetic fields and accelerating cavities
  • 2.4. Disk loaded cavities and accelerating conditions
  • 2.5. The linac design key quantities
  • 2.6. Phase stability in linacs
  • 2.7. Beam qualities and accelerating field
  • 2.8. Complements and exercises
  • 3. Free-electron-based generators of electromagnetic radiation
  • 3.1. An introduction to the process of emission/absorption of photons by free electrons
  • 3.2 Electron-field energy exchange
  • 3.3. Coherent generation of radiation by a charged particle beam
  • 3.4. A single cavity as a basic structure
  • 3.5. General form of the electron-field coupling coefficient in cylindrical cavities
  • 3.6. The klystron
  • 3.7. The travelling wave amplifier
  • 3.8. The backward wave oscillator
  • 3.9. Electron-based source characteristics and limitations
  • 3.10. Radiation by moving charges and synchrotron radiation emission
  • 3.11. The magnetic undulator
  • 3.12. The gain mechanism
  • 4. Linac-based free electron laser devices : oscillator and single passage operating modes
  • 4.1. Introduction
  • 4.2. Free electron laser
  • 4.3. The FEL small signal equation low and high-gain regimes
  • 4.4. FEL oscillators : a preliminary analysis
  • 4.5. FEL oscillators : mode locking
  • 4.6. Designing an FEL-O device
  • 4.7. High-gain FEL devices
  • 4.8. High-gain FEL equation and the relevant consequences
  • 4.9. Concluding comments
  • 4.10. Complements and exercises
  • 5. Compact FEL devices and new acceleration schemes
  • 5.1. Introduction
  • 5.2. Plasma acceleration : preliminary concepts
  • 5.3. Plasma acceleration : beam production and scaling identities
  • 5.4. FEL and laser plasma accelerated beams : general considerations
  • 5.5. FEL operating with laser wave undulators : general considerations
  • 5.6. Concluding comments
  • 5.7. Complements and exercises.

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