A practical introduction to beam physics and particle accelerators /

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This book provides a brief exposition of the principles of beam physics and particle accelerators with an emphasis on numerical examples employing readily available computer tools.

Detalles Bibliográficos
Clasificación:Libro Electrónico
Autor principal: Bernal, Santiago (Autor)
Formato: Electrónico eBook
Idioma:Inglés
Publicado: Bristol [England] (Temple Circus, Temple Way, Bristol BS1 6HG, UK) : IOP Publishing, [2022]
Edición:Third edition.
Colección:IOP (Series). Release 22.
IOP ebooks. 2022 collection.
Temas:
Particle beams.
Particle accelerators.
Particle & high-energy physics.
SCIENCE / Physics / Atomic & Molecular.
Acceso en línea:Texto completo
Tabla de Contenidos:
  • 1. Rays, matrices, and transfer maps
  • 1.1. Paraxial approximation
  • 1.2. Thin lenses
  • 1.3. Thick lenses
  • 1.4. Transfer maps
  • 1.5. Computer resources
  • 2. Linear magnetic lenses and deflectors
  • 2.1. Magnetic rigidity, momentum, and cyclotron frequency
  • 2.2. Solenoid focusing
  • 2.3. Quadrupole focusing
  • 2.4. The Kerst-Serber equations and weak focusing
  • 2.5. Dipoles and edge focusing
  • 2.6. Computer resources
  • 3. Periodic lattices and functions
  • 3.1. Solenoid lattice
  • 3.2. FODO lattice
  • 3.3. Lattice and beam functions
  • 3.4. Uniform-focusing ('smooth') approximation
  • 3.5. Linear dispersion
  • 3.6. Momentum compaction, transition gamma, and chromaticity
  • 3.7. Computer resources
  • 4. Emittance and space charge
  • 4.1. Liouville's theorem and emittance
  • 4.2. The Kapchinskij-Vladimirskij (K-V) and thermal distributions
  • 4.3. Thermodynamics of charged-particle beams?
  • 4.4. The K-V envelope equations and space-charge (SC) intensity parameters
  • 4.5. Incoherent space-charge (SC) betatron tune shift
  • 4.6. Coherent tune shift and Laslett coefficients
  • 4.7. Computer resources
  • 5. Beam (sigma) matrix and coupled optics
  • 5.1. Solenoid focusing revisited
  • 5.2. Skew quadrupole
  • 5.3. Beam (sigma) matrix
  • 5.4. Coupled optics
  • 5.5. Angular momentum and the envelope equation in solenoid
  • 5.6. Round-to-flat (RTF) and flat-to-round (FTR) beam adapters
  • 5.7. Computer resources
  • 6. Longitudinal beam dynamics and radiation
  • 6.1. Radio-frequency (RF) linacs
  • 6.2. Beam bunch stability and RF buckets
  • 6.3. Synchrotron radiation
  • 6.4. Insertion devices and free-electron lasers (FELs)
  • 6.5. Longitudinal beam emittance and space charge
  • 6.6. Computer resources
  • 7. Envelope matching, resonances, and dispersion
  • 7.1. Cell envelope FODO matching
  • 7.2. Source-to-cell envelope matching
  • 7.3. Betatron resonances
  • 7.4. Betatron resonances and space charge
  • 7.5. Dispersion and space charge
  • 7.6. Computer resources
  • 8. Linacs and rings (examples), closed orbit, and beam cooling
  • 8.1. Examples of linacs
  • 8.2. Examples of rings
  • 8.3. Closed orbit and correction
  • 8.4. Beam cooling
  • 8.5. Computer resources
  • 9. Small machines and scaled experiments
  • 9.1. The University of Maryland Electron Ring (UMER) : a storage ring for space-charge research
  • 9.2. Small Isochronous Ring (SIR) : space-charge effects in the isochronous regime
  • 9.3. Integrable optics and other physics in IOTA
  • 9.4. Fixed-field alternating-gradient accelerators (FFAGs) : lessons from EMMA
  • 9.5. Beam stability and betatron resonances : Paul traps as model accelerators
  • 9.6. Computer resources
  • Appendix A. Computer resources and their use
  • Appendix B. Accelerator magnets.

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