Collimated $ \gamma $-flash emission along the target surface irradiated by a laser at non-grazing incidence

TL;DR

This paper demonstrates through 3D simulations that oblique laser incidence on a solid target can produce a collimated gamma-photon beam along the target surface, influenced by interference patterns and electron acceleration.

Contribution

It introduces a novel regime where oblique laser incidence generates surface-directed gamma-ray beams, expanding understanding of laser-target interactions.

Findings

Collimated gamma-ray emission occurs along the target surface at oblique incidence.

The emission depends on incident angle, polarization, laser power, and target properties.

High-order harmonics are also generated propagating along the target surface.

Abstract

The interaction of a high-power laser with a solid target provides ways to produce beams of $\gamma$-photons. For normal incidence of the laser on the target the beams usually appear in a form of two lobes, which are symmetric with respect to the laser propagation axis. In this work we demonstrate via three-dimensional particle-in-cell simulations a regime where for oblique incidence the emission of a collimated $\gamma$-photon beam is in the direction parallel to the target surface. The process is ascribed to the interference pattern in the electromagnetic field formed by the incident and reflected laser pulse. The electromagnetic field accelerates electrons to the GeV energy level, while temporarily directing their momentum along the target surface. Consequently, they emit a collimated $\gamma$-photon beam in the same direction. The dependencies of $\gamma$-photon emission on the incident angle, laser pulse polarization, power and duration and target thickness and preplasma are also addressed in the paper. The beam directionality is important for designing future experiments. In addition, this setup causes the generation of high-order harmonics propagating along the target surface.