Production of multi-oriented polarization for relativistic electron beams via a mutable filter for nonlinear Compton scattering

TL;DR

This paper presents a novel method to produce relativistic electron beams with controllable polarization directions using a filter mechanism during nonlinear Compton scattering, demonstrated through simulations.

Contribution

It introduces a new scheme employing a filter to achieve high-degree polarization in relativistic electron beams with arbitrary directions.

Findings

Polarization up to 62% in transverse directions.

Longitudinal polarization up to 10%.

Robustness demonstrated across various parameters.

Abstract

We propose a feasible scenario to directly polarize a relativistic electron beam and obtain overall polarization in various directions through a filter mechanism for single-shot collision between an ultrarelativistic unpolarized electron beam and an ultraintense circularly polarized laser pulse. The electrons are scattered to a large angular range of several degrees and the polarization states of the electrons are connected with their spatial position after the collision. Therefore, we can employ a filter to filter out a part of the scattered electrons based on their position and obtain high-degree overall polarization for the filtered beam. Through spin-considered Monte-Carlo simulations, polarization with a degree up to 62% in arbitrary transverse directions and longitudinal polarization up to 10% are obtained for the filtered beams at currently achievable laser intensity. We theoretically analyze the distribution formation of the scattered electrons and investigate the influence of different initial parameters through simulations to demonstrate the robustness of our scheme. This scenario provides a simple and flexible way to produce relativistic polarized electron beams for various polarization directions.