Collisional processes and size distribution in spatially extended debris discs

TL;DR

This paper introduces a multi-annulus model for debris discs, revealing how collisions and radial mixing affect size and spatial distributions, with implications for interpreting observational data.

Contribution

It develops a new multi-annulus code that models collisional evolution and radial mixing in debris discs, extending previous single-annulus studies and providing empirical formulas for size distribution.

Findings

Size distribution departs from classical power law, especially for observable particles.

Small grains' spatial distribution is significantly altered by radiation pressure effects.

Empirical formulas for size distribution and collision timescale are provided.

Abstract

We present a new multi-annulus code for the study of collisionally evolving extended debris discs. We first aim to confirm results obtained for a single-annulus system, namely that the size distribution in "real" debris discs always departs from the theoretical collisional equilibrium $dN\proptoR^{-3.5}dR$ power law, especially in the crucial size range of observable particles (<1cm), where it displays a characteristic wavy pattern. We also aim at studying how debris discs density distributions, scattered light luminosity profiles, and SEDs are affected by the coupled effect of collisions and radial mixing due to radiation pressure affected small grains. The size distribution evolution is modeled from micron-sized grains to 50km-sized bodies. The model takes into account the crucial influence of radiation pressure-affected small grains. We consider the collisional evolution of a fiducial a=120AU radius disc with an initial surface density in $\Sigma(a)\propto a^{\alpha}$. We show that the system's radial extension plays a crucial role: in most regions the collisional and size evolution of the dust is imposed by small particles on eccentric or unbound orbits produced further inside the disc. The spatial distribution of small grains strongly departs from the initial profile, while the bigger objects, containing most of the system's mass, still follow the initial distribution. This has consequences on the scattered--light radial profiles which get significantly flatter, and we propose an empirical law to trace back the distribution of large unseen parent bodies from the observed profiles. We finally provide empirical formula for the collisional size distribution and collision timescale that can be used for future debris disc modeling.