Drifting discrete Jovian radio bursts reveal acceleration processes related to Ganymede and the main aurora

Radio detection at high time-frequency resolutions is a powerful means of remotely studying electron acceleration processes. Radio bursts have characteristics (polarization, drift, periodicity) making them easier to detect than slowly variable emissions. They are not uncommon in solar system planetary magnetospheres, the powerful Jovian short bursts (S-bursts) induced by the Io-Jupiter interaction being especially well-documented. Here we present a detection method of drifting radio bursts in terabytes of high resolution time-frequency data, applied to one month of ground-based Jupiter observations. Beyond the expected Io-Jupiter S-bursts, we find decameter S-bursts related to the Ganymede-Jupiter interaction and the main Jovian aurora, revealing ubiquitous Alfvenic electron acceleration in Jupiter's high-latitude regions. Our observations show accelerated electron energies are distributed in two populations, kilo-electron-Volts and hundreds of electron-Volts. This detection technique may help characterizing inaccessible astrophysical sources such as exoplanets. Jovian short bursts (S-bursts) are induced by the Io-Jupiter interaction. Here, the authors show a drifting radio burst detection method and report S-bursts related to Ganymede-Jupiter interaction and to Jovian aurora.

Automated summary

Radio detection at high time-frequency resolutions is an effective method to study electron acceleration processes, and radio bursts from Jupiter have characteristics that make them easier to detect than slowly variable emissions. In addition to Io-Jupiter S-bursts, drifting radio bursts related to Ganymede-Jupiter interaction and Jovian aurora were found, showing ubiquitous Alfvenic electron acceleration in Jupiter's high-latitude regions.