Rapid charge redistribution leading to core hollowing in a high-intensity ion beam

TL;DR

This paper investigates how rapid charge redistribution causes core hollowing in high-intensity ion beams, revealing phenomena that are often hidden in phase space projections and comparing them to similar effects in laser-ionized nanoclusters.

Contribution

It demonstrates that nonlinear space charge forces induce hollowing in beam distributions, providing new insights into beam dynamics and core-correlated structures.

Findings

Hollowed, double-peaked energy distribution observed

Hollowing caused by velocity perturbation from nonlinear space charge

Self-consistent RFQ simulation reproduces observed structures

Abstract

Recently, the first direct measurement of a full 6D accelerator beam distribution was reported [1]. That work observed a correlation between energy and transverse coordinates, for which the energy distribution becomes hollowed and double-peaked near the transverse core. In this article, a similar structure is shown to emerge in expansion of an initially uncorrelated, high density bunched beam as the result of velocity perturbation from nonlinear space charge forces. This hollowing is obscured when the 6D phase space is projected onto one- and two-dimensional axes. This phenomenon has not been widely recognized in accelerator systems, but parallels can be drawn to observations of laser-ionized nanoclusters and electron sources for diffraction. While this effect provides insight into the origin of the measured core correlation, it does not provide a complete description. A better reproduction of the measured structure can be obtained via self-consistent simulation through the radio-frequency quadrupole. [1] B. Cathey, S. Cousineau, A. Aleksandrov, and A. Zhukov, PRL 121, 064804 (2018).