The Dynamical Viability of an Extended Jupiter Ring System

TL;DR

This study uses N-body simulations to investigate the potential for stable, dense ring material around Jupiter, revealing regions where rings could exist and insights into their formation and sustainability.

Contribution

It provides the first detailed dynamical analysis of Jupiter's ring system constraints using long-term N-body simulations.

Findings

Stable ring regions are limited by Galilean satellites.

Dense ring material is dynamically desiccated within 3-29 Jupiter radii.

Implications for exoplanetary ring and moon system coexistence.

Abstract

Planetary rings are often speculated as being a relatively common attribute of giant planets, partly based on their prevalence within the Solar System. However, their formation and sustainability remain a topic of open discussion, and the most massive planet within our planetary system harbors a very modest ring system. Here, we present the results of a N-body simulation that explores dynamical constraints on the presence of substantial ring material for Jupiter. Our simulations extend from within the rigid satellite Roche limit to 10\% of the Jupiter Hill radius, and include outcomes from $10^6$ and $10^7$ year integrations. The results show possible regions of a sustained dense ring material presence around Jupiter that may comprise the foundation for moon formation. The results largely demonstrate the truncation of stable orbits imposed by the Galilean satellites, and dynamical desiccation of dense ring material within the range $\sim$3--29 Jupiter radii. We discuss the implications of these results for exoplanets, and the complex relationship between the simultaneous presence of rings and massive moon systems.