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Self-consistent long-term dynamics of space charge driven resonances in 2D and 3D

Hofmann, Ingo ; Oeftiger, Adrian ; Boine-Frankenheim, Oliver (2021)
Self-consistent long-term dynamics of space charge driven resonances in 2D and 3D.
In: Physical Review Accelerators and Beams, 24 (2)
doi: 10.1103/PhysRevAccelBeams.24.024201
Article, Bibliographie

Abstract

Understanding the 3D collective long-term response of beams exposed to resonances is of theoretical interest and essential for advancing high intensity synchrotrons. This study of a hitherto unexplored beam dynamical regime is based on 2D and 3D self-consistent particle-in-cell simulations and on careful analysis using tune spectra and phase space. It shows that in Gaussian-like beams Landau damping suppresses all coherent parametric resonances, which are of higher than second order (the “envelope instability”). Our 3D results are obtained in an exemplary stopband, which includes the second order coherent parametric resonance and a fourth order structural resonance. They show that slow synchrotron oscillation plays a significant role. Moreover, for the early time evolution of emittance growth the interplay of incoherent and coherent resonance response matters, and differentiation between halo and different core regions is essential. In the long-term behavior we identify a progressive, self-consistent drift of particles toward and across the resonance, which results in effective compression of the initial tune spectrum. However, no visible imprint of the coherent features is left over, which only control the picture during the first one or two synchrotron periods. An intensity limit criterion and an asymptotic formula for long-term rms emittance growth are suggested. Comparison with the commonly used non-self-consistent “frozen space charge” model shows that in 3D this approximation yields a fast and useful orientation, but it is a conservative estimate of the tolerable intensity.

Item Type: Article
Erschienen: 2021
Creators: Hofmann, Ingo ; Oeftiger, Adrian ; Boine-Frankenheim, Oliver
Type of entry: Bibliographie
Title: Self-consistent long-term dynamics of space charge driven resonances in 2D and 3D
Language: English
Date: 15 February 2021
Publisher: APS
Journal or Publication Title: Physical Review Accelerators and Beams
Volume of the journal: 24
Issue Number: 2
DOI: 10.1103/PhysRevAccelBeams.24.024201
Abstract:

Understanding the 3D collective long-term response of beams exposed to resonances is of theoretical interest and essential for advancing high intensity synchrotrons. This study of a hitherto unexplored beam dynamical regime is based on 2D and 3D self-consistent particle-in-cell simulations and on careful analysis using tune spectra and phase space. It shows that in Gaussian-like beams Landau damping suppresses all coherent parametric resonances, which are of higher than second order (the “envelope instability”). Our 3D results are obtained in an exemplary stopband, which includes the second order coherent parametric resonance and a fourth order structural resonance. They show that slow synchrotron oscillation plays a significant role. Moreover, for the early time evolution of emittance growth the interplay of incoherent and coherent resonance response matters, and differentiation between halo and different core regions is essential. In the long-term behavior we identify a progressive, self-consistent drift of particles toward and across the resonance, which results in effective compression of the initial tune spectrum. However, no visible imprint of the coherent features is left over, which only control the picture during the first one or two synchrotron periods. An intensity limit criterion and an asymptotic formula for long-term rms emittance growth are suggested. Comparison with the commonly used non-self-consistent “frozen space charge” model shows that in 3D this approximation yields a fast and useful orientation, but it is a conservative estimate of the tolerable intensity.

Divisions: 18 Department of Electrical Engineering and Information Technology
18 Department of Electrical Engineering and Information Technology > Institute for Accelerator Science and Electromagnetic Fields > Accelerator Physics
18 Department of Electrical Engineering and Information Technology > Institute for Accelerator Science and Electromagnetic Fields
Date Deposited: 16 Feb 2023 09:56
Last Modified: 15 Jun 2023 09:40
PPN: 508618622
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