Helical Electron Beam Micro-Bunching by High-Order Modes in a Micro-Plasma Waveguide

TL;DR

This paper demonstrates how high-order modes in a micro-plasma waveguide excited by a Laguerre-Gaussian laser can produce high-energy, highly charged, ultrashort, and helically micro-bunched electron beams, with potential for scientific and practical applications.

Contribution

It introduces a novel method to generate helical micro-bunched electron beams using high-order waveguide modes excited by circularly polarized Laguerre-Gaussian pulses.

Findings

High-energy (~100 MeV), high-charge (~10 nC) electron beams are produced.

The electron beams exhibit helical micro-bunching imprinted by the waveguide modes.

The process is controllable via the laser's spin and orbital angular momentum.

Abstract

Electron acceleration by a high-power Laguerre-Gaussian pulse in a micro-plasma waveguide is investigated. When the incident laser travels in the waveguide, electrons on the wall are extracted into the vacuum core and accelerated by the longitudinal field of the waveguide mode. Using 3D particle-in-cell simulations, we demonstrate that high energy (~100 MeV) electron beams with extremely high charge (~10 nC), ultrashort duration (~30 fs) and small divergence (~1 deg) can be produced by a 100-TW, few-Joule class laser system. In particular, when the drive Laguerre-Gaussian pulse is circularly polarized, it excites high-order waveguide modes that exhibit helical longitudinal electric fields. The 3D profile of this accelerating field is imprinted into the high energy electron beam, leading to helical micro-bunching. This process can be controlled by the spin and orbital angular momentum of the drive pulse. This work paves the way to the generation of highcharge, relativistic electron beams with controlled helicity, which holds great potential for advances in fundamental science and a variety of applications.