Orbital evolution of Saturn's satellites due to the interaction between the moons and massive Saturn's rings

TL;DR

This study uses high-resolution N-body simulations to show that self-gravity wakes in Saturn's rings can cause rapid satellite migration, potentially explaining the current orbital resonances of Saturn's moons.

Contribution

It demonstrates that self-gravity wakes significantly influence satellite orbital evolution, offering a new mechanism for avoiding resonance trapping.

Findings

Self-gravity wakes induce faster satellite migration than spiral arms.

Rapid migration helps explain current orbital resonances of Saturn's moons.

Self-gravity wakes act as an effective driver for satellite orbital evolution.

Abstract

Saturn's mid-sized moons (satellites) have a puzzling orbital configuration with trapping in mean-motion resonances with every other pairs (Mimas-Tethys 4:2 and Enceladus-Dione 2:1). To reproduce their current orbital configuration on the basis of Crida & Charnoz's model of satellite formation from a hypothetical ancient massive rings, adjacent pairs must pass 1st-order mean-motion resonances without being trapped. The trapping could be avoided by fast orbital migration and/or excitation of the satellite's eccentricity caused by gravitational interactions between the satellites and the rings (the disk), which are still unknown. In our research, we investigate the satellite orbital evolution due to interactions with the disk through full N-body simulations. We performed global high-resolution N-body simulations of a self-gravitating particle disk interacting with a single satellite. We used $N \sim 10^5$ particles for the disk. Gravitational forces of all the particles and their inelastic collisions are taken into account. As a result, dense short-wavelength wake structure is created by the disk self-gravity and global spiral arms with $m \sim$ a few is induced by the satellite. The self-gravity wakes regulate the orbital evolution of the satellite, which has been considered as a disk spreading mechanism but not as a driver for the orbital evolution. The self-gravity wake torque to the satellite is so effective that the satellite migration is much faster than that was predicted with the spiral arms torque. It provides a possible model to avoid the resonance capture of adjacent satellite pairs and establish the current orbital configuration of Saturn's mid-sized satellites.