Plasma rotation driven by lasers with zero angular momentum

TL;DR

This paper introduces a new mechanism where plasma gains angular momentum from lasers with zero angular momentum through local pump depletion, enabling control over high-energy electron transverse momentum.

Contribution

It reveals a novel plasma angular momentum acquisition process driven by azimuthally polarized lasers and demonstrates control over electron transverse momentum via laser parameter variation.

Findings

Plasma electrons and ions acquire angular momentum during laser depletion.

Angular momentum transfer is balanced by ions and electromagnetic fields.

Laser parameters influence high-energy electron transverse momentum.

Abstract

We present a novel mechanism in which plasma electrons and ions optically acquire angular momentum during local pump depletion of an azimuthally polarized laser, despite the laser carrying none. Using theoretical considerations and multi-dimensional particle-in-cell simulations, we find that this process is enabled by a strong frequency downshift at the gradually eroding laser pulse front. We further show that the angular momentum gained by the plasma electrons is compensated by the ions and by the combined electromagnetic fields of the laser and nonlinear plasma wave. By varying key laser parameters such as phase, frequency, and polarization, we demonstrate that the transverse momentum of high-energy electrons can be effectively controlled.