Fast ion instability in real lattice

Author

Stupakov, G.V.

Author_Institution

Linear Accel. Center, Stanford Univ., CA, USA

Volume

2

fYear

1997

fDate

12-16 May 1997

Firstpage

1632

Abstract

The ionization of residual gas by an electron beam in an accelerator generates ions that can resonantly couple to the beam through a wave propagating in the beam-ion system. The original theory of the fast ion instability was developed assuming both a constant external focusing and the beam size. The theory predicts an instability in which an initial perturbation grows as ~exp(α√t). In the present paper we consider a more realistic model that takes into account variation of the beta function in the lattice and associated with it variation of the beam size. We find that, in combination with ion decoherence effect, the spatial inhomogeneity can result in (1) purely exponential growth, ~exp(Γt), and (2) typically smaller growth rates. Detailed calculations are performed for the lattice of the Advanced Light Source at the LBL

Keywords

X-ray production; electron accelerators; electron beam focusing; electron beams; particle beam stability; perturbation theory; storage rings; LBL Advanced Light Source; accelerator; beam size; beam-ion system; beta function variation; constant external focusing; electron beam; fast ion instability; initial perturbation; ion decoherence; purely exponential growth; real lattice; residual gas ionization; spatial inhomogeneity; Electron accelerators; Electron beams; Electron traps; Frequency; Ion accelerators; Ionization; Lattices; Light sources; Linear accelerators; Resonance;

fLanguage

English

Publisher

ieee

Conference_Titel

Particle Accelerator Conference, 1997. Proceedings of the 1997

Conference_Location

Vancouver, BC

Print_ISBN

0-7803-4376-X

Type

conf

DOI

10.1109/PAC.1997.750782

Filename

750782