Using Kuiper Belt Binaries to Constrain Neptune's Migration History

TL;DR

This paper proposes using the distribution of binaries in Kuiper belt resonances to distinguish between different models of Neptune's migration, providing a new method to understand planetary formation history.

Contribution

It introduces a novel approach to differentiate Neptune's migration scenarios by analyzing binary fractions in Kuiper belt resonant objects, linking orbital characteristics to migration processes.

Findings

Migration-induced capture predicts a cold component in the 2:1 resonance with high binary fraction.

Chaotic capture results in randomized orbits, lacking the predicted cold component.

Specific binary fraction trends correlate with orbital eccentricities, aiding in migration scenario identification.

Abstract

Approximately 10-20% of all Kuiper belt objects (KBOs) occupy mean-motion resonances with Neptune. This dynamical configuration likely resulted from resonance capture as Neptune migrated outward during the late stages of planet formation. The details of Neptune's planetesimal-driven migration, including its radial extent and the concurrent eccentricity evolution of the planet, are the subject of considerable debate. Two qualitatively different proposals for resonance capture have been proposed--migration-induced capture driven by smooth outward evolution of Neptune's orbit and chaotic capture driven by damping of the planet's eccentricity near its current semi-major axis. We demonstrate that the distribution of comparable-mass, wide-separation binaries occupying resonant orbits can differentiate between these two scenarios. If migration-induced capture occurred, this fraction records information about the formation locations of different populations of KBOs. Chaotic capture, in contrast, randomizes the orbits of bodies as they are placed in resonance. In particular, migration-induced capture produces the following signatures. The 2:1 resonance should contain a dynamically cold component, with inclinations less than 5-10 degrees, having a binary fraction comparable to that among cold classical KBOs. If the 3:2 resonance also hosts a cold component, its binary fraction should be 20-30% lower than in the cold classical belt. Among cold 2:1 (and if present 3:2) KBOs, objects with eccentricities e < 0.2 should have a binary fraction ~20% larger than those with e > 0.2. Searches for cold components in the binary fractions of resonant KBOs are currently practical. The additional migration-generated trends described here may be distinguished with objects discovered by LSST. (Abstract abridged.)