Generation of relativistic polarized electron beams via collective beam-target interactions

TL;DR

This paper proposes a novel method to generate relativistic polarized electron beams through collective beam-target interactions, utilizing magnetic fields and spin-dependent radiation reactions to achieve over 50% polarization.

Contribution

It introduces a new approach for efficient electron spin polarization using collective interactions and magnetic pinching effects in relativistic beams.

Findings

Electron polarization can exceed 50% for energies below 2 GeV.

Strong magnetic fields of a few Giga-Gauss are induced at the target surface.

The method enables robust polarized electron source development.

Abstract

Relativistic polarized electron beams can find applications in broad areas of fundamental physics. Here, we propose for the first time that electron spin polarization can be realized efficiently via collective beam-target interactions. When a relativistic unpolarized electron beam is incident onto the surface of a solid target with a grazing angle, strong magnetic fields are induced at the target surface due to the formation of a high reflux of target electrons. This results in violent beam self-focusing and corresponding beam density increase via magnetic pinching. The pinched dense beam in turn further enhances the magnetic fields to the level of a few Giga-Gauss, which is high enough to trigger strong synchrotron radiation of ultrarelativistic electrons. During the interaction, electron spin polarization develops along the magnetic field direction, which is achieved via radiative spin flips in the quantum radiation-dominated regime. As a consequence, the incident electron beam can be effectively polarized via the spin-dependent radiation reaction, for example, the mean polarization of electrons with energy less than 2 GeV can reach above 50% for an initial 5GeV beam. This provides a robust way for the development of polarized electron sources.