An extended locally constant field approximation for nonlinear Compton scattering

TL;DR

This paper introduces an improved approximation method called LCFA+ for nonlinear Compton scattering, enhancing accuracy over the traditional LCFA in simulating quantum processes in intense laser fields.

Contribution

The authors derive LCFA+ to address limitations of existing corrections, providing a more accurate and implementable approximation for quantum emission in strong laser fields.

Findings

LCFA+ outperforms LCFA across the entire photon spectrum.

The method aligns well with full QED results.

Implementation in numerical codes is demonstrated.

Abstract

The locally constant field approximation (LCFA) has to date underpinned the numerical simulation of quantum processes in laser-plasma physics and astrophysics, but its validity has recently been questioned in the parameter regime of current laser experiments. While improvements are needed, literature corrections to the LCFA show inherent problems. Using nonlinear Compton scattering in laser fields to illustrate, we show here how to overcome the problems in LCFA corrections. We derive an "LCFA+" which, comparing with the full QED result, shows an improvement over the LCFA across the whole photon emission spectrum. We also demonstrate an implementation of our results in the type of numerical code used to design and analyse intense laser experiments.