The Atomic Hydrogen Cloud in the Saturnian System

TL;DR

This study models the sources and distribution of atomic hydrogen in Saturn's magnetosphere, highlighting the dominant role of Titan and Saturn's atmosphere, and explaining observed asymmetries and density variations.

Contribution

It provides a comprehensive global model of hydrogen sources in Saturn's system, integrating multiple origins and their effects on hydrogen cloud morphology.

Findings

Titan's hydrogen escape significantly shapes the outer magnetosphere.

Saturn's atmosphere is a major hydrogen source, especially near the planet.

Dissociation processes and particle collisions influence hydrogen distribution and asymmetry.

Abstract

The Voyager flyby observations revealed that a very broad doughnut shaped distribution of the hydrogen atoms existed in the Saturnian magnetosphere. Recent Cassini observations confirmed the local-time asymmetry but also showed the hydrogen cloud density increases with decreasing distance to Saturn. The origin of the atomic hydrogen cloud has been debated ever since. Therefore, we have carried out a global investigation of the atomic hydrogen cloud taking into account all possible sources: 1) the Saturnian atmosphere, 2) the H2 atmosphere of main rings, 3) Enceladus H2O and OH torus, 4) Titan H2 torus and 5) the atomic hydrogen directly escaping from Titan. We show that the H ejection velocity and angle distribution are modified by collisions of the hot H, produced by electron-impact dissociation of H2, with the ambient atmospheric H2 and H. This in turn affects the morphology of the escaping hydrogen as does the morphology of the ionospheric electron distribution. That Saturn atmosphere is an important source is suggested by the fact that the H cloud peaks well below the ring plane, a feature that, so far, we can not reproduce by the dissociation of the ring H2 atmosphere or other proposed sources. Our simulations show that H directly escaping from Titan is a major contribution in the outer magnetosphere. The morphology of Titan H torus, shaped by the solar radiation pressure and the Saturnian oblateness, can account for the local time asymmetry near Titan orbit. Dissociation of H2O and OH in the Enceladus torus contributes inside ~5 RS, but dissociation of Titan H2 torus does not due to the significant energy released. The total number of H observed by Cassini inside 5 RS: our modeling results suggest ~20% from dissociation in the Enceladus torus, ~10% from dissociation of ring H2 atmosphere, and ~50% from Titan H torus implying that ~20% comes from the Saturnian atmosphere.