Laser-triggered THz emission from near critical density targets

TL;DR

This paper demonstrates through 3D simulations that femtosecond laser pulses in a relativistic self-trapping regime can efficiently generate high-energy, quasi-unipolar THz pulses from near-critical density targets, surpassing standard methods.

Contribution

It introduces the use of relativistic self-trapping regime in near-critical density plasma for enhanced THz emission, showing significant improvements over traditional foil targets.

Findings

THz pulses with energy over 100 mJ can be generated.

Relativistic self-trapping regime enhances charge and conversion efficiency.

Simulation results outperform standard preplasma foil targets.

Abstract

Femtosecond laser pulse propagation in a relativistic self-trapping regime (RST) in a near-critical density plasma makes it possible to maximize the total charge of the accelerating electrons and laser-to-electrons conversion rate, that can be used to provide a large amount of the THz range coherent transition radiation. The three-dimensional particle-in-cell simulations demonstrate how such transition radiation generates when electrons escape into vacuum either from the low-density target itself, or after passing through a thin foil located at the target end. Advantage of the RST regime for generation of THz pulses is clearly demonstrated as compared to laser irradiation of such a standard target as a foil with preplasma on its front side. Simulation performed has shown that for the optimized laser-target matching a 2-J femtosecond laser pulse is able to produce quasi-unipolar Thz pulses with energy exceeding 100 mJ.