Debris discs in binaries: a numerical study

TL;DR

This study uses numerical simulations to investigate how debris discs in binary star systems evolve dynamically, considering factors like perturbations, radiation pressure, and collisional processes, revealing that discs extend beyond stability limits and are depleted of small grains.

Contribution

It provides the first detailed numerical analysis of debris disc evolution in binary systems accounting for collisional activity and radiation pressure effects.

Findings

Discs extend beyond the critical semimajor axis due to small grain production.

The amount of matter beyond the stability limit depends on disc mass and binary eccentricity.

Small grains are depleted in the stable regions, affecting observable signatures.

Abstract

Debris disc analysis and modelling provide crucial information about the structure and the processes at play in extrasolar planetary systems. In binary systems, this issue is more complex because the disc should in addition respond to the companion star's perturbations. We explore the dynamical evolution of a collisionally active debris disc for different initial parent body populations, diverse binary configurations and optical depths. We focus on the radial extent and size distribution of the disc at a stationary state. We numerically follow the evolution of $10^{5}$ massless small grains, initially produced from a circumprimary disc of parent bodies following a size distribution in $dN \propto s^{-3.5}$ds . Grains are submitted to both stars' gravity as well as radiation pressure. In addition, particles are assigned an empirically derived collisional lifetime. For all the binary configurations the disc extends far beyond the critical semimajor axis $a_crit$ for orbital stability. This is due to the steady production of small grains, placed on eccentric orbits reaching beyond $a_crit$ by radiation pressure. The amount of matter beyond acrit depends on the balance between collisional production and dynamical removal rates: it increases for more massive discs as well as for eccentric binaries. Another important effect is that, in the dynamically stable region, the disc is depleted from its smallest grains. Both results could lead to observable signatures. We have shown that a companion star can never fully truncate a collisionally active disc. For eccentric companions, grains in the unstable regions can significantly contribute to the thermal emission in the mid-IR. Discs with sharp outer edges, especially bright ones such as HR4796A, are probably shaped by other mechanisms.