High-harmonic Plasma Emission Induced by Electron Beams in Weakly Magnetized Plasmas
Abstract
Electromagnetic radiation at higher harmonics of the plasma frequency (ω nωpe, n > 2) has been occasionally observed in type II and type III solar radio bursts, yet the underlying mechanism remains undetermined. Here we present two-dimensional fully kinetic electromagnetic particle-in-cell simulations with high spectral resolution to investigate the beam-driven plasma emission process in weakly magnetized plasmas of typical coronal conditions. We focused on the generation mechanisms of high-harmonic emission. We found that a larger beam velocity (ud) favors the generation of the higher-harmonic emission. The emissions grow later for higher harmonics and decrease in intensity by 2 orders of magnitude for each jump of the harmonic number. The second and third harmonic ( H2 and H3) emissions get closer in intensity with larger ud. We also show that (1) the H3 emission is mainly generated via the coalescence of the H2 emission with the Langmuir waves, i.e., H2 + L → H3, wherein the coalescence with the forward-propagating beam-Langmuir wave leads to the forward-propagating H3, and coalescence with the backward-propagating Langmuir wave leads to the backward-propagating H3; and (2) the H4 emission mainly arises from the coalescence of the H3 emission with the forward- (backward-) propagating Langmuir wave, in terms of H3 + L → H4.
Turn this paper into a full lesson
ArcXiv compiles a staged curriculum from this paper: 8-12 lessons across beginner → advanced, synthesised section guides, visuals, flashcards, a quiz, exercises, and on-demand deep dives per section. Grounded in the abstract, never invented.