Polarization ratios of turbulent Langmuir/Z-mode waves generated by electron beams in magnetized solar wind plasmas

Abstract

The polarization ratios F=|E|2/|E|2 of beam-generated turbulent Langmuir/Z-mode (LZ) waves and electromagnetic emissions radiated at plasma frequency ωp by such sources are studied in weakly magnetized and randomly inhomogeneous plasmas owing to large-scale and long-term 2D/3V Particle-In-Cell simulations with parameters relevant to type III solar radio bursts. Statistical studies using waveforms recorded by virtual satellites are performed to determine the distributions of polarization ratios as a function of beam and plasma parameters. This efficient method, which mimics waveform recording by spacecraft in the solar wind, leads to results consistent with observations. Moreover, plasma random density fluctuations δ n turn out to be the key factor responsible for the increase in polarization ratios up to F 1. Indeed, it is demonstrated that linear mode conversion at constant frequency of LZ waves scattering on δ n is the most efficient and fast process to produce large polarization ratios in randomly inhomogeneous plasmas, due to electromagnetic slow extraordinary Z-mode wave emission by LZ wave turbulence. Results provide guidance to theoretical studies and useful support to estimate the average level of density fluctuations N in solar wind plasmas.