What and Whence 1I/`Oumuamua: A Contact Binary from the Debris of a Young Planetary System?

TL;DR

`Oumuamua is likely a contact binary from a young planetary system, exhibiting extreme elongation and variability, possibly due to its origin and surface evolution in a debris disk, challenging previous comet-like assumptions.

Contribution

The paper proposes that `Oumuamua is a contact binary from a young star system, explaining its shape, variability, and lack of ices through formation and surface processes.

Findings

`Oumuamua's shape suggests a contact binary structure.

Its motion aligns with a young stellar association.

Lack of ices can be explained by size and surface evolution.

Abstract

The first confirmed interstellar interloper in our Solar System, 1I/`Oumuamua, is likely to be a minor body ejected from another star, but its brief flyby and faintness made it difficult to study. Two remarkable properties are its large (up to 2.5 mag) rotational variability and its motion relative to the Sun before encounter. The former suggests an extremely elongated shape (aspect ratio ~10) and the latter an origin from the protoplanetary disk of a young star in a nearby association. Against expectations, it is also not comet-like. 1I/`Oumuamua's variability can also be explained if it is a contact binary composed of near-equilibrium ellipsoidal components and heterogeneous surfaces, i.e. brighter, dust-mantled inner-facing hemispheres and darker, dust-free outer-facing poles. Such shapes are a plausible outcome of radiation, tides and collisions in systems where planets are clearing planetesimal disks. The probability that 1I/`Oumuamua has the same motion as a young (<~100 Myr) stellar association by coincidence is <1%. If it is young, its detection vs. more numerous, older counterparts could be explained as a selection effect due to darkening of surfaces by Galactic cosmic rays and loss of dust. 1I/`Oumuamua's apparent lack of ices can be explained if ejected rocky planetesimals are characteristically smaller and thus far more numerous than their icy counterparts: the Solar System may currently host several such objects captured by the combined gravity of Jupiter and the Sun.