First-year ion-acoustic wave observations in the solar wind by the RPW/TDS instrument onboard Solar Orbiter.

Electric field measurements of the Time Domain Sampler (TDS) receiver, a part of the Radio and Plasma Waves (RPW) instrument on-board Solar Orbiter, often exhibit very intense broadband wave emissions at frequencies below 20~kHz in the spacecraft frame. During the first year of the mission, the RPW/TDS instrument has been operating from the first perihelion in mid-June 2020 and through the first flyby of Venus in late December 2020. In this paper, a year-long study of electrostatic fluctuations observed in the solar wind at an interval of heliocentric distances from 0.5 to 1~AU is shown. The on-board processed properties of waveform snapshots that are continuously collected allow mapping plasma waves at frequencies between 200~Hz and 20~kHz. For a detailed spectral and polarization analysis, the triggered waveform snapshots and a Doppler-shifted solution of the dispersion relation for wave mode identification were used. The occurrence rate of low-frequency waves peaks around perihelion at distances of 0.5~AU and decreases with increasing distances, with only a few waves detected per day at 0.9~AU. A more detailed analysis of more than ten thousand triggered waveform snapshots shows the median wave frequency at about 2.3~kHz and wave amplitude about 1.1~mV/m. The relative phase distribution between two components of E-field projected in the Y-Z Spacecraft Reference Frame (SRF) plane shows a mostly linear wave polarization. Electric field fluctuations are closely aligned with the directions of the ambient field lines. The observed waves are interpreted as the strongly Doppler-shifted electrostatic ion-acoustic mode generated by the resonant interaction with ion beams or by the current-driven instability.