Phase space exchange-based bunch compression with reduced CSR effects

TL;DR

This paper introduces a novel phase space exchange-based bunch compression scheme that significantly reduces CSR effects through asymmetric design, optimization, and nonlinear dynamics analysis, improving beam quality in accelerators.

Contribution

The paper presents a new asymmetric double emittance exchange scheme with optimized parameters and nonlinear dynamics analysis to mitigate CSR effects in bunch compression.

Findings

Self-compensation of CSR effects demonstrated in simulations

Optimized asymmetric scheme improves transverse and longitudinal beam quality

Incorporation of sextupoles enhances nonlinear beam dynamics control

Abstract

Through an interaction of theory and optimization-guided design, we have developed a novel bunch compression scheme based on an asymmetric double emittance exchange (DEEX) with greatly reduced coherent synchrotron radiation (CSR) effects. First, we discuss the benefits of the phase space exchange-based bunch compressor (BC) in comparison to the chicane-based counterpart in the approximation of linear single particle dynamics and with respect to microbunching instabilities driven by longitudinal space charge forces. We present simulation results for nonlinear dynamics in a symmetric DEEX BC which accounts for the CSR effects of the scheme with direct and mirrored longitudinal phase space at the exit of the beamline. The later scheme demonstrates self-compensation of CSR effects on the longitudinal dynamics. Next, we optimize the parameters of the beam elements with an adaptive feedback, resulting in an asymmetric configuration of the scheme with compensated CSR and nonlinear effects on the transverse dynamics, which we further improve by incorporating several sextupoles relying on an eigen-emittance analysis. Finally, we discuss how this method can be generalized for optimizing nonlinear beam dynamics with collective effects.