Nonlinear Breit-Wheeler pair production using polarized photons from inverse Compton scattering

TL;DR

This paper proposes a two-stage Monte Carlo simulation to generate polarized gamma rays via inverse Compton scattering and demonstrates the feasibility of observing nonlinear Breit-Wheeler pair production and related phenomena with current laser and electron beam technology.

Contribution

It introduces a novel experimental configuration and simulation approach for producing polarized gamma rays and studying pair production in high-intensity laser fields.

Findings

Feasible measurement of gamma-ray polarization dependence in pair production.

Potential to observe harmonic structures and transition from perturbative to nonperturbative regimes.

Use of current 100-TW class lasers and electron beams for near-term experiments.

Abstract

Observing multiphoton electron-positron pair production (the nonlinear Breit-Wheeler process) requires high-energy $\gamma$ rays to interact with strong electromagnetic fields. In order for these observations to be as precise as possible, the $\gamma$ rays would ideally be both mono-energetic and highly polarized. Here we perform Monte Carlo simulations of an experimental configuration that accomplishes this in two stages. First, a multi-GeV electron beam interacts with a moderately intense laser pulse to produce a bright, highly polarized beam of $\gamma$ rays by inverse Compton scattering. Second, after removing the primary electrons, these $\gamma$ rays collide with another, more intense, laser pulse in order to produce pairs. We show that it is possible to measure the $\gamma$-ray polarization dependence of the nonlinear Breit-Wheeler process in near-term experiments, using a 100-TW class laser and currently available electron beams. Furthermore, it would also be possible to observe harmonic structure and the perturbative-to-nonperturbative transition if such a laser were colocated with a future linear collider.