Compositions and origins of outer planet systems: Insights from the Roche critical density

TL;DR

This paper explores the Roche critical density to understand the composition and origins of outer planet systems, revealing differences in material density and formation processes between rings and moons.

Contribution

It introduces a method to infer the composition and formation history of planetary rings and moons based on Roche critical density comparisons.

Findings

Uranus' rings are likely more rocky and less porous than Saturn's.

Inner moons of Jupiter and Neptune may be denser or migrated objects.

Uranus' Portia group resembles an accretion-dominated ring system.

Abstract

We consider the Roche critical density (rho_Roche), the minimum density of an orbiting object that, at a given distance from its planet, is able to hold itself together by self-gravity. It is directly related to the more familiar "Roche limit," the distance from a planet at which a strengthless orbiting object of given density is pulled apart by tides. The presence of a substantial ring requires that transient clumps have an internal density less than rho_Roche. Conversely, in the presence of abundant material for accretion, an orbiting object with density greater than rho_Roche will grow. Comparing the rho_Roche values at which the Saturn and Uranus systems transition rapidly from disruption-dominated (rings) to accretion-dominated (moons), we infer that the material composing Uranus' rings is likely more rocky, as well as less porous, than that composing Saturn's rings. From the high values of rho_Roche at the innermost ring-moons of Jupiter and Neptune, we infer that those moons may be composed of denser material than expected, or more likely that they are interlopers that formed farther from their planets and have since migrated inward, now being held together by internal material strength. Finally, the "Portia group" of eight closely-packed Uranian moons has an overall surface density similar to that of Saturn's A ring. Thus, it can be seen as an accretion-dominated ring system, of similar character to the standard ring systems except that its material has a characteristic density greater than the local rho_Roche.