The Secular Dynamics of TNOs and Planet Nine Interactions

TL;DR

This paper investigates the secular dynamics of trans-Neptunian objects influenced by a hypothetical Planet Nine, revealing mechanisms for orbital alignment, flipping, and the impact of planetary parameters on TNO distributions.

Contribution

It provides a detailed analysis of how an eccentric Planet Nine can produce observed TNO orbital clustering and flips through secular interactions, expanding understanding beyond previous coplanar models.

Findings

Secular interactions can produce long-term TNO orbital clustering.

Planet Nine can flip TNO orbital planes and cause pericenter libration.

Eccentric Planet Nine with specific parameters explains observed TNO distributions.

Abstract

The existence of Planet Nine has been suggested to explain the pericenter clustering of extreme trans-Neptunian objects (TNOs). However, the underlying dynamics involving Planet Nine, test particles and Neptune is rich, and it remains unclear which dynamical processes lead to the alignment and how they depends on the properties of Planet Nine. Here, we investigate the secular interactions between an eccentric outer perturber and TNOs starting in a near-coplanar configuration. We find that a large number of TNOs could survive outside of mean motion resonances at 4Gyr, which differs from previous results obtained in the exact coplanar case with Neptune being treated as a quadrupole potential. In addition, secular dynamics leads to the orbital clustering seen in N-body simulations. We find that a near coplanar Planet Nine can flip TNO orbital planes, and when this happens, the geometrical longitudes of pericenter of the TNOs librate around $180^\circ$ during the flip. Orbital precession caused by the inner giant planets can suppress the flips while keeping the longitude of pericenter librating when $30\lesssim r_p \lesssim 80$ AU $\&$ $a\gtrsim 250$ AU. This results in the alignment of the pericenter of the low inclination TNOs ($i \lesssim 40^\circ$). We find the anti-aligned population and the flipped orbits could be produced by an eccentric ($e_9 \gtrsim 0.4$) outer planet of $\sim 10M_{\oplus}$ in a wide $a_9 \gtrsim 400 \sim 800$ AU orbit. Future surveys on the high inclination TNOs will help further constrain the properties of possible outer planets.