Collimated gamma-ray beams from structured laser-irradiated targets -- how to increase the efficiency without increasing the laser intensity

Abstract

Using three-dimensional kinetic simulations, we examine the emission of collimated gamma-ray beams from structured laser-irradiated targets with a pre-filled cylindrical channel. The channel guides the incident laser pulse, enabling generation of a slowly evolving azimuthal plasma magnetic field that serves two key functions: to enhance laser-driven electron acceleration and to induce emission of gamma-rays by the energetic electrons. Our main finding is that the conversion efficiency of the laser energy into a beam of gamma-rays (5 opening angle) can be significantly increased without increasing the laser intensity by utilizing channels with an optimal density. The conversion efficiency into multi-MeV photons increases roughly linearly with the incident laser power P, as we increase P from 1 PW to 4 PW while keeping the laser peak intensity fixed at 5 × 1022 W/cm2. This scaling is achieved by using an optimal range of plasma densities in the channel between 10 and 20 ncr, where ncr is the classical cutoff density for electromagnetic waves. The corresponding number of photons scales as P2. One application that directly benefits from such a strong scaling is the pair production via two-photon collisions, with the number of generated pairs increasing as P4 at fixed laser intensity.