The evolution of large cavities and disc eccentricity in circumbinary discs

TL;DR

This study uses 3D simulations to explore how circumbinary discs and their binary stars evolve, revealing that disc eccentricity develops even from circular initial conditions and affects cavity structure, with implications for planet formation.

Contribution

It demonstrates the development of disc eccentricity in high mass ratio binaries and links it to cavity size, providing new insights into disc-binary interactions and evolution.

Findings

Disc eccentricity grows abruptly after 400-700 binary orbits.

Disc eccentricity correlates linearly with cavity size.

Over-dense features in the disc may trap dust, affecting observations.

Abstract

We study the mutual evolution of the orbital properties of high mass ratio, circular, co-planar binaries and their surrounding discs, using 3D Smoothed Particle Hydrodynamics simulations. We investigate the evolution of binary and disc eccentricity, cavity structure and the formation of orbiting azimuthal over-dense features in the disc. Even with circular initial conditions, all discs with mass ratios $q>0.05$ develop eccentricity. We find that disc eccentricity grows abruptly after a relatively long time-scale ($\sim 400\textrm{--}700$ binary orbits), and is associated with a very small increase in the binary eccentricity. When disc eccentricity grows, the cavity semi-major axis reaches values $a_{\rm cav}\approx 3.5\, a_{\rm bin}$. We also find that the disc eccentricity correlates linearly with the cavity size. Viscosity and orbit crossing, appear to be responsible for halting the disc eccentricity growth -- eccentricity at the cavity edge in the range $e_{\rm cav}\sim 0.05\textrm{--} 0.35$. Our analysis shows that the current theoretical framework cannot fully explain the origin of these evolutionary features when the binary is almost circular ($e_{\rm bin}\lesssim 0.01$); we speculate about alternative explanations. As previously observed, we find that the disc develops an azimuthal over-dense feature in Keplerian motion at the edge of the cavity. A low contrast over-density still co-moves with the flow after 2000 binary orbits; such an over-density can in principle cause significant dust trapping, with important consequences for protoplanetary disc observations.