A method for accurate and efficient simulations of slow beam degradation due to electron clouds

TL;DR

This paper introduces a symplectic simulation method for modeling slow beam degradation caused by electron clouds in particle accelerators, enabling accurate long-term predictions of beam quality.

Contribution

It presents a novel symplectic approach using tricubic interpolation for efficient, accurate simulation of electron cloud effects in complex accelerator lattices.

Findings

Successfully applied to LHC proton beam at injection energy

Accurately predicts beam losses and emittance growth

Enables detailed dynamic aperture and frequency analysis

Abstract

In the Large Hadron Collider, electron clouds have been observed to cause slow beam degradation in the form of beam lifetime reduction and slow emittance growth. We present a method for the simulation of such slow effects with arbitrarily complex electron clouds and in the presence of non-linearities in the lattice of the accelerator. The application of the electron cloud forces, as obtained from a particle-in-cell simulation of the electron cloud dynamics, is kept symplectic by using an appropriate tricubic interpolation scheme. The properties of such an interpolation scheme are studied in detail and numerical artifacts that can be introduced by the scheme are identified and corrected through a suitable refinement procedure. The method is applied to the case of the Large Hadron Collider for protons at injection energy to compute Dynamic Aperture, to perform Frequency Map Analysis, and to simulate beam losses and emittance growth by tracking particle distributions for long time scales.