Relativistic two-wave resonant acceleration of electrons at large-amplitude standing whistler waves during laser-plasma interaction

TL;DR

This paper demonstrates that relativistic two-wave resonant acceleration in standing whistler waves during laser-plasma interaction significantly enhances hot electron generation, with potential applications in laser-driven ion acceleration.

Contribution

It introduces a novel mechanism for hot electron acceleration via standing whistler waves under strong magnetic fields, supported by detailed PIC simulations and analysis.

Findings

Efficient hot electron generation occurs when standing wave magnetic field exceeds ambient field.

A bifurcation in electron gyration enables relativistic energies for non-relativistic electrons.

Hot electron numbers increase drastically compared to unmagnetized cases.

Abstract

The interaction between a thin foil target and a circularly polarized laser light injected along an external magnetic field is investigated numerically by particle-in-cell simulations. A standing wave appears at the front surface of the target, overlapping the injected and partially reflected waves. Hot electrons are efficiently generated at the standing wave due to the relativistic two-wave resonant acceleration if the magnetic field amplitude of the standing wave is larger than the ambient field. A bifurcation occurs in the gyration motion of electrons, allowing all electrons with non-relativistic velocities to acquire relativistic energy through the cyclotron resonance. The optimal conditions for the highest energy and the most significant fraction of hot electrons are derived precisely through a simple analysis of test-particle trajectories in the standing wave. Since the number of hot electrons increases drastically by many orders of magnitude compared to the conventional unmagnetized cases, this acceleration could be a great advantage in laser-driven ion acceleration and its applications.