Controlling the polarization and vortex charge of $\gamma$ photons via nonlinear Compton scattering

TL;DR

This paper demonstrates a method to generate and control high-energy vortex gamma photons with specific polarization and vortex charge using nonlinear Compton scattering of two-color circularly polarized lasers, enabling tailored angular momentum transfer.

Contribution

The study introduces a novel approach to manipulate the polarization and vortex charge of gamma photons via laser parameter tuning in nonlinear Compton scattering.

Findings

Controlled generation of vortex gamma photons with specific angular momentum.

The angular momentum transfer depends on the dominant photon absorption channel.

Tuning laser intensities allows customization of photon polarization and vortex charge.

Abstract

High-energy vortex $\gamma$ photons have significant applications in many fields, however, their generation and angular momentum manipulation are still great challenges. Here, we first investigated the generation of vortex $\gamma$ photons with controllable spin and orbital angular momenta via nonlinear Compton scattering of two-color counter-rotating circularly polarized (CP) laser fields. The radiation probabilities of vortex photons are calculated using the semiclassical approach that resolves angular momenta of emitted photons. We find that the angular momenta transferred to emitted photons are determined by the dominating photon absorption channel, leading to a structured spectrum with alternations in helicity and twist directions. By tuning the relative intensity ratio of the two-color CP laser fields, %the preferred photon absorption channel can be enhanced, providing the polarization and vortex charge of the emitted $\gamma$ photons can be controlled, enabling the generation of circularly polarized vortex $\gamma$ photons with a user-defined polarization and topological charge, which may have a plenty of applications in nuclear physics, astrophysics, particle physics, etc.