Inclination pathways of planet-crossing asteroids

TL;DR

This paper develops an analytical framework based on the Tisserand relation to explain the inclination pathways of planet-crossing asteroids, revealing how their long-term evolution depends on initial inclination and Tisserand parameter.

Contribution

It introduces an analytical approach using the Tisserand relation to predict inclination pathways of asteroids, supported by numerical simulations, enhancing understanding of their orbital evolution.

Findings

Asteroids with I_infinity > 110 deg cannot enter the planet's orbit.

Inclination pathways are constrained within 45 deg. to 110 deg. for certain Tisserand parameters.

Secular perturbations influence inclination dispersion, especially for polar orbits.

Abstract

Long-term statistical simulations of the past evolution of high-inclination Centaurs showed that their orbits tend to be polar with respect to the solar system's invariable plane over a large semi-major axis range in trans-neptunian space. Here, we lay the analytical foundation of the study of the inclination pathways of planet-crossing asteroids that explains these findings. We show that the Tisserand relation partitions the inclination-semi-major axis parameter space of the three-body problem into distinct regions depending on the asteroid's Tisserand parameter T or equivalently its orbital inclination I_infinity far from the planet. The Tisserand relation shows that asteroids with I_infinity > 110 deg. (T < -1) cannot be injected inside the planet's orbit. Injection onto retrograde orbits and high-inclination prograde orbits occurs inside the inclination corridor 45 deg. < I_infinity < 110 deg. (-1< T < 2). Inclination dispersion across the inclination pathway for moderate and high inclinations is explained by the secular perturbations from the planet and is smallest for polar orbits. When a planet-crossing asteroid temporarily leaves the inclination pathway, its long term evolution still depends on its Tisserand parameter as evidenced by its eccentricity dispersion. Simulations of asteroid orbits using the equations of motion with Neptune as the perturbing planet confirm these results for moderate to high inclinations, forward and backward in time because the Tisserand relation is time independent. The Tisserand inclination pathways will provide important constraints on comet delivery from the outer solar system as well as on the possible presence of unknown planets in trans-neptunian space.