Charged beam dynamics, particle accelerators and free electron lasers /
Saved in:
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: | |
Format: | E-Resource Book |
URL for this record: | http://pi.lib.uchicago.edu/1001/cat/bib/11432362 |
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.