Effects of Coherent Synchrotron Radiation in Bunch Compressor of TARLA

• Authors: H. Yildiz , A. Aksoy , P. Arikan
• Languages of publication: EN

Abstracts

EN

High order and non-linear effects in accelerator beamline play an important role in the transport of the beam. These effects cause variation of designed beam parameters such as emittance growth, bunch length variation, beam halo formation, etc. One of the known non-linear effects in bunch compressors is the coherent synchrotron radiation effect. In this study we focus on coherent synchrotron radiation effect in Turkish Accelerator and Radiation Laboratory in Ankara (TARLA) machine which is designed to drive Infrared Free Electron Laser, covering the range of 3-250 μm. We additionally discuss high order effects in bunch compressor of TARLA.

Keywords

EN

29.27.Bd; 29.27.-a; 29.20.Ej; 41.60.-m; 41.60.Cr; 41.85.Ja; 41.85.-p; 07.55.Db; 02.10.Yn

Discipline

• 02.10.Yn: Matrix theory
• 41.85.Ja: Particle beam transport
• 41.60.Cr: Free-electron lasers(see also 52.59.Rz Free-electron devices—in plasma physics)
• 41.60.-m: Radiation by moving charges
• 29.20.Ej: Linear accelerators
• 29.27.-a: Beams in particle accelerators(for low energy charged-particle beams, see 41.75.-i and 41.85.-p)
• 29.27.Bd: Beam dynamics; collective effects and instabilities
• 07.55.Db: Generation of magnetic fields; magnets(for superconducting magnets, see 84.71.Ba; for beam focusing magnets, see 41.85.Lc in beam optics)
• 41.85.-p: Beam optics(see also 07.77.Ka Charged-particle beam sources and detectors in instruments; 29.27.-a Beams in particle accelerators)

• Journal: Acta Physica Polonica A
• Year: 2016
• Volume: 130
• Issue: 1
• Pages: 214-216

Dates

published

2016-07

Contributors

author

H. Yildiz

• Gazi University, Physics Department, Ankara, Turkey

author

A. Aksoy

• Ankara University, Institute of Accelerator Technologies, Ankara, Turkey

author

P. Arikan

• Gazi University, Physics Department, Ankara, Turkey

References

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Identifiers

DOI

10.12693/APhysPolA.130.214