On the stability around Chariklo and the confinement of its rings

TL;DR

This study investigates the stability of Chariklo's rings and explores confinement mechanisms, finding that shepherd satellites and resonances can explain the rings' current positions and stability.

Contribution

The paper introduces a detailed numerical and dynamical analysis of Chariklo's rings, proposing a three-satellite confinement mechanism based on resonance and stability studies.

Findings

Inner edge of stable region is closer to Chariklo than the rings.

Resonant orbits and islands correspond to specific ring locations.

A three-satellite system can effectively confine the rings.

Abstract

Chariklo has two narrow and dense rings, C1R and C2R, located at 391 km and 405 km, respectively. In the light of new stellar occultation data, we study the stability around Chariklo. We also analyse three confinement mechanisms, to prevent the spreading of the rings, based on shepherd satellites in resonance with the edges of the rings. This study is made through a set of numerical simulations and the Poincar\'e surface of section technique. From the numerical simulation results we verify that, from the current parameters referring to the shape of Chariklo, the inner edge of the stable region is much closer to Chariklo than the rings. The Poincar\'e surface of sections allow us to identify the first kind periodic and quasi-periodic orbits, and also the resonant islands corresponding to the 1:2, 2:5, and 1:3 resonances. We construct a map of a versus e space which gives the location and width of the stable region and the 1:2, 2:5, and 1:3 resonances. We found that the first kind periodic orbits family can be responsible for a stable region whose location and size meet that of C1R, for specific values of the ring particles' eccentricities. However, C2R is located in an unstable region if the width of the ring is assumed to be about 120 m. After analysing different systems we propose that the best confinement mechanism is composed of three satellites, two of them shepherding the inner edge of C1R and the outer edge of C2R, while the third satellite would be trapped in the 1:3 resonance.