Cloud-based design of high average power traveling wave linacs

The design of industrial high average power traveling wave linacs must accurately consider some specific effects. For example, acceleration of high current beam reduces power flow in the accelerating waveguide. Space charge may influence the stability of longitudinal or transverse beam dynamics. Acc...

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Bibliographic Details
Published in:Journal of physics. Conference series 2017-12, Vol.941 (1), p.12106
Main Authors: Kutsaev, S V, Eidelman, Y, Bruhwiler, D L, Moeller, P, Nagler, R, Barbe Welzel, J
Format: Article
Language:English
Subjects:
Beams (radiation)
Codes
Differential equations
Dynamic stability
Equations of motion
Flow stability
Graphical user interface
Particle accelerators
Particle in cell technique
Physics
Power flow
Space charge
Traveling waves
Waveguides
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Summary:The design of industrial high average power traveling wave linacs must accurately consider some specific effects. For example, acceleration of high current beam reduces power flow in the accelerating waveguide. Space charge may influence the stability of longitudinal or transverse beam dynamics. Accurate treatment of beam loading is central to the design of high-power TW accelerators, and it is especially difficult to model in the meter-scale region where the electrons are nonrelativistic. Currently, there are two types of available codes: tracking codes (e.g. PARMELA or ASTRA) that cannot solve self-consistent problems, and particle-in-cell codes (e.g. Magic 3D or CST Particle Studio) that can model the physics correctly but are very time-consuming and resource-demanding. Hellweg is a special tool for quick and accurate electron dynamics simulation in traveling wave accelerating structures. The underlying theory of this software is based on the differential equations of motion. The effects considered in this code include beam loading, space charge forces, and external magnetic fields. We present the current capabilities of the code, provide benchmarking results, and discuss future plans. We also describe the browser-based GUI for executing Hellweg in the cloud.
ISSN:1742-6588
1742-6596
DOI:10.1088/1742-6596/941/1/012106