Space-charge effects in low-energy flat-beam transforms

TL;DR

This paper investigates how space-charge effects influence flat-beam transforms in low-energy, high-current electron beams, revealing linear effects that can be compensated and nonlinear effects that limit device performance.

Contribution

It provides the first analysis of space-charge effects in FBTs at low energies, identifying linear compensation methods and nonlinear limitations.

Findings

Linear effects can be compensated by retuning FBTs and adding quadrupoles.

Nonlinear effects cause emittance dilution and power limitations.

Space-charge effects are significant in vacuum electron devices at low energies.

Abstract

Flat-beam transforms (FBTs) provide a technique for controlling the emittance partitioning between the beam's two transverse dimensions. To date, nearly all FBT studies have been in regimes where the beam's own space-charge effects can be ignored, such as in applications with high-brightness electron linacs where the transform occurs at high, relativistic, energies. Additionally, FBTs may provide a revolutionary path to high power generation at high frequencies in vacuum electron devices where the beam emittance is currently becoming a limiting factor, which is the focus of this paper. Electron beams in vacuum electron devices operate both at a much lower energy and a much higher current than in accelerators and the beam's space charge forces can no longer be ignored. Here we analyze the effects of space-charge in FBTs and show there are both linear and nonlinear forces and effects. The linear effects can be compensated by retuning the FBT and by adding additional quadrupole elements. The nonlinear effects lead to an ultimate dilution of the lower recovered emittance and will lead to an eventual power limitation for high-frequency traveling-wave tubes and other vacuum electron devices.