Theory of terahertz emission from femtosecond-laser-induced micro-plasmas

TL;DR

This paper presents a comprehensive theoretical model for terahertz emission from femtosecond-laser-induced micro-plasmas, incorporating ionization, heating, and multiple emission mechanisms, validated by simulations and applicable to various plasma configurations.

Contribution

It introduces a unified model that combines ionization current and transition-Cherenkov mechanisms for THz emission, providing insights into their relative importance and scaling behavior.

Findings

Transition-Cherenkov mechanism dominates for multi-cycle laser pulses.

Oscillations at plasma frequency do not contribute to THz emission.

Simplified model agrees well with particle-in-cell simulations.

Abstract

We present a theoretical investigation of terahertz (THz) generation in laser-induced gas plasmas. The work is strongly motivated by recent experimental results on micro-plasmas, but our general findings are not limited to such a configuration. The electrons and ions are created by tunnel-ionization of neutral atoms, and the resulting plasma is heated by collisions. Electrons are driven by electromagnetic, convective and diffusive sources and produce a macroscopic current which is responsible for THz emission. The model naturally includes both, ionization current and transition-Cherenkov mechanisms for THz emission, which are usually investigated separately in the literature. The latter mechanism is shown to dominate for single-color multi-cycle lasers pulses, where the observed THz radiation originates from longitudinal electron currents. However, we find that the often discussed oscillations at the plasma frequency do not contribute to the THz emission spectrum. In order to predict the scaling of the conversion efficiency with pulse energy and focusing conditions, we propose a simplified description that is in excellent agreement with rigorous particle-in-cell simulations.