New high power linacs and beam physics

Author

Wangler, T.P. ; Gray, E.R. ; Nath, S. ; Crandall, K.R. ; Hasegawa, K.

Author_Institution

Los Alamos Nat. Lab., NM, USA

Volume

1

fYear

1997

fDate

12-16 May 1997

Firstpage

915

Abstract

New high-power proton linacs must be designed to control beam loss, which can lead to radioactivation of the accelerator. The threat of beam loss is increased significantly by the formation of beam halo. Numerical simulation studies have identified the space-charge interactions, especially those that occur in rms mismatched beams, as a major concern for halo growth. The maximum-amplitude predictions of the simulation codes must be subjected to independent tests to confirm the validity of the results. Consequently, we compare predictions from the particle-core halo models with computer simulations to test our understanding of the halo mechanisms that are incorporated in the computer codes. We present and discuss scaling laws that provide guidance for high-power linac design

Keywords

linear accelerators; particle beam diagnostics; particle beam stability; proton accelerators; beam halo; beam loss; computer simulation; halo growth; high-power proton linac; maximum-amplitude; particle-core halo models; scaling laws; space-charge interaction; Computational modeling; Computer simulation; Linear accelerators; Numerical simulation; Particle beams; Physics; Predictive models; Proton accelerators; Radio control; Testing;

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.1997.749882

Filename

749882