Callisto's Nonresonant Orbit as an Outcome of Circum-Jovian Disk Substructure

TL;DR

This paper proposes that a disk pressure bump can explain Callisto's nonresonant orbit by acting as a migration trap, influencing the orbital architecture of the Galilean moons through self-consistent N-body simulations.

Contribution

It introduces a novel disk substructure mechanism, specifically a pressure bump, as an alternative to late accretion for explaining Callisto's orbit, supported by detailed simulations.

Findings

A pressure bump can trap Callisto, preventing resonance with inner moons.

The bump's structure must be within a specific 'Goldilocks' range for observed orbital configuration.

Simulations show sequential trapping and resonant migration of moons at the bump.

Abstract

The Galilean moons of Io, Europa, and Ganymede exhibit a 4:2:1 commensurability in their mean motions, a configuration known as the Laplace resonance. The prevailing view for the origin of this three-body resonance involves the convergent migration of the moons, resulting from gas-driven torques in the circum-Jovian disk wherein they accreted. To account for Callisto's exclusion from the resonant chain, a late and/or slow accretion of the fourth and outermost Galilean moon is typically invoked, stalling its migration. Here, we consider an alternative scenario in which Callisto's nonresonant orbit is a consequence of disk substructure. Using a suite of N-body simulations that self-consistently account for satellite-disk interactions, we show that a pressure bump can function as a migration trap, isolating Callisto and alleviating constraints on its timing of accretion. Our simulations position the bump interior to the birthplaces of all four moons. In exploring the impact of bump structure on simulation outcomes, we find that it cannot be too sharp nor flat to yield the observed orbital architecture. In particular, a "Goldilocks" zone is mapped in parameter space, corresponding to a well-defined range in bump aspect ratio. Within this range, Io, Europa, and Ganymede are sequentially trapped at the bump, and ushered across it through resonant lockstep migration with their neighboring, exterior moon. The implications of our work are discussed in the context of uncertainties regarding Callisto's interior structure, arising from the possibility of non-hydrostatic contributions to its shape and gravity field, unresolved by the Galileo spacecraft.