A low-inclination neutral Trans-Neptunian Object in a extreme orbit

TL;DR

This study investigates the unique orbit and color of the trans-Neptunian object 2016 SD$_{106}$, using observations and simulations to explore its origins and the potential influence of a hypothetical distant planet.

Contribution

It provides the first detailed analysis of 2016 SD$_{106}$'s orbit and color, and explores the role of a hypothetical planet in producing similar objects.

Findings

2016 SD$_{106}$'s orbit is metastable with no significant scattering over 1 Gyr.

Few low-inclination neutral objects are found in the outer solar system.

A hypothetical distant planet can produce similar orbits, but contradicts observed scarcity.

Abstract

We present photometric observations and numerical simulations of 2016 SD$_{106}$, a low inclination ($i=4.8^{\circ}$) extreme trans-Neptunian Object with a large semi-major axis ($a=350$ au) and perihelion ($q= 42.6$ au). This object possesses a peculiar neutral color of $g-r = 0.45\pm0.05$ and $g-i=0.72\pm0.06$, in comparison with other distant trans-Neptunian objects, all of which have moderate-red to ultra-red colors. A numerical integration based on orbital fitting on astrometric data covering eight years of arc confirms that 2016 SD$_{106}$ is a metastable object without significant scattering evolution. Each of the clones survived at the end of the 1 Gyr simulation. However, very few neutral objects with inclinations $<5^{\circ}$ have been found in the outer solar system, even in the main Kuiper belt. Furthermore, most mechanisms which lift perihelion distances are expected to produce a very low number of extreme objects with inclinations $<5^{\circ}$. We thus explored the possibility that a hypothetical distant planet could increase the production of such objects. Our simulations show that no 2016 SD$_{106}$-like orbits can be produced from three Kuiper belt populations tested (i.e. plutinos, twotinos, and Haumea Family) without the presence of an hypothetical planet, while a few similar orbits can be obtained with it; however, the presence of the additional planet produces a wide range of large semimajor-axis / large perihelion objects, in apparent contradiction with the observed scarcity of objects in those regions of phase space. Future studies may determine if there is a connection between the existence of a perihelion gap and a particular orbital configuration of an hypothetical distant planet.