Polarization control of electron injection and acceleration in the plasma by a self steepening laser pulse

TL;DR

This paper introduces a novel method called EPUB, where a self-steepening laser pulse induces bubble undulations in plasma, enabling precise control over electron injection, resulting in high-charge, ultra-short electron beams with potential for polarized betatron radiation.

Contribution

The study presents the concept of CEP-controlled bubble undulation (EPUB) for controlled electron injection in plasma acceleration, a new approach leveraging laser self-steepening effects.

Findings

EPUB produces high-charge, high-current electron beams.

Laser polarization and power control the electron bunch structure.

Potential for generating polarized betatron radiation.

Abstract

We describe an interplay between two injection mechanism of background electrons into an evolving plasma bubble behind an intense laser pulse: one due to the overall bubble expansion, and another due to its periodic undulation. The two mechanisms occur simultaneously when an intense laser pulse propagating inside a plasma forms a shock like steepened front. Periodic undulations of the plasma bubble along the laser propagation path can either inhibit or conspire with electron injection due to bubble expansion. We show that Carrier Envelope Phase (CEP) controlled plasma bubble undulation induced by the self steepening laser pulse produces a unique electron injector: Expanding Phase controlled Undulating Bubble (EPUB). The longitudinal structure of the electron bunch injected by the EPUB can be controlled by laser polarization and power, resulting in high-charge (multiple nano Coulombs) high-current (tens of kilo Amperes) electron beams with ultra short (femtosecond scale) temporal structure. Generation of high energy betatron radiation with polarization and CEP controlled energy spectrum and angular distribution is analyzed as a promising application of EPUB produced beams.