Stability of Satellites in Closely Packed Planetary Systems

TL;DR

This study uses numerical simulations to assess the stability of satellites in tightly-packed multi-planet systems, finding that most such systems can support satellites with only slight reductions in stability zones compared to single-planet systems.

Contribution

It provides the first detailed analysis of satellite stability in multi-planet systems, revealing that these systems can generally host satellites despite complex gravitational interactions.

Findings

Most stable two-planet systems can support satellites similar to single-planet cases.

Stable prograde satellites extend out to about 0.4 Hill radii.

Close planetary pairs can destabilize satellites, especially in resonant configurations.

Abstract

We perform numerical integrations of four-body (star, planet, planet, satellite) systems to investigate the stability of satellites in planetary Systems with Tightly-packed Inner Planets (STIPs). We find that the majority of closely-spaced stable two-planet systems can stably support satellites across a range of parameter-space which is only slightly decreased compared to that seen for the single-planet case. In particular, circular prograde satellites remain stable out to $\sim 0.4 R_H$ (where $R_H$ is the Hill Radius) as opposed to $\sim 0.5 R_H$ in the single-planet case. A similarly small restriction in the stable parameter-space for retrograde satellites is observed, where planetary close approaches in the range 2.5 to 4.5 mutual Hill radii destabilize most satellites orbits only if $a\sim 0.65 R_H$. In very close planetary pairs (e.g. the 12:11 resonance) the addition of a satellite frequently destabilizes the entire system, causing extreme close-approaches and the loss of satellites over a range of circumplanetary semi-major axes. The majority of systems investigated stably harbored satellites over a wide parameter-space, suggesting that STIPs can generally offer a dynamically stable home for satellites, albeit with a slightly smaller stable parameter-space than the single-planet case. As we demonstrate that multi-planet systems are not a priori poor candidates for hosting satellites, future measurements of satellite occurrence rates in multi-planet systems versus single-planet systems could be used to constrain either satellite formation or past periods of strong dynamical interaction between planets.