Disruption of exo-asteroids around white dwarfs and the release of dust particles in debris rings in co-orbital motion

TL;DR

This study investigates the dynamics of dust and debris rings around white dwarfs caused by asteroid disruption near the Roche radius, revealing stable co-orbital configurations and their implications for observed debris disks.

Contribution

It provides the first detailed analysis of co-orbital dust dynamics at extremely low mass ratios in the CRTBP, including new unstable 3D families and stability maps for white dwarf systems.

Findings

Stable dust configurations can persist over observable timescales without external forces.

Maximum orbital period deviations are only a few seconds over 10 years.

Unstable debris typically deviates by more than 20 km from co-orbital positions.

Abstract

Close to the Roche radius of a white dwarf (WD), an asteroid on a circular orbit sheds material that then adopts a very similar orbit. Observations of the resulting debris show a periodic behavior and changes in flux on short timescales, implying ongoing dynamical activity. Additional encounters from other minor planets may then yield co-orbital rings of debris at different inclinations. The structure, dynamics, and lifetime of these debris discs remains highly uncertain, but is important for understanding WD planetary systems. We aim to identify and quantify the locations of co-orbitals in WD-asteroid-dust particle 3-body systems by exploring the influence of 1:1 resonant periodic orbits. We begin this exploration with co-planar and inclined orbits in the circular restricted 3-body problem (CRTBP) and model the dynamical evolution of these exosystems over observable timescales. The mass ratio parameter for this class of systems ($~2\times 10^{-11}$) is one of the lowest ever explored in this dynamical configuration. We computed the periodic orbits, deduced their linear stability, and suitably seeded the dynamical stability maps. We carried out a limited suite of N-body simulations to provide direct comparisons with the maps. We derive novel results for this extreme mass ratio in the CRTBP, including new unstable 3D families. We illustrate through the maps and N-body simulations where dust can exist in a stable configuration over observable timescales across a wide expanse of parameter space in the absence of strong external forces. Over a timescale of 10 yr, the maximum orbital period deviations of stable debris due to the co-orbital perturbations of the asteroid is about a few seconds. Unstable debris in a close encounter with the asteroid typically deviates from the co-orbital configuration by more than about 20 km and is on a near-circular orbit with an eccentricity lower than ~0.01.