Weakened Inspirals I: High Mass Ratio Common Envelope Interactions in RGB Stars

TL;DR

This study uses 3D hydrodynamical simulations to explore how high mass ratios affect common envelope interactions in RGB stars, revealing wider post-CE separations and potential circumbinary disc formation.

Contribution

It demonstrates that high mass ratio systems result in wider post-CE orbits and favor fallback disc formation, challenging traditional CE evolution models.

Findings

Higher mass ratios lead to wider post-CE separations, up to 40 Rsun.

For q ≥ 1, the inspiral phase becomes more stable and longer.

Fallback discs form outside the binary, consistent with observed circumbinary discs.

Abstract

The common envelope (CE) interaction between an expanding giant star and a compact companion typically leads to a rapid orbital decay, ending in either a merger or the formation of a close binary. However, the existence of post-red giant and post-asymptotic giant branch binaries with separations of 100 to 800 Rsun challenges this standard picture, as these systems appear to have experienced strong interactions without undergoing a classic CE inspiral. In this work, we investigate the effect of high mass ratio, q = M2/M1, on the CE inspiral using three-dimensional hydrodynamical simulations performed with the smoothed particle hydrodynamics code PHANTOM. The primary is a 0.88 Msun, 90 Rsun red giant branch star, while the companion masses span q = 0.68 to 1.5. Higher mass ratios lead to wider post-CE separations, with a maximum of approximately 40 Rsun. The pre-CE mass transfer phase is longer for larger companion masses, and for q greater than or equal to 1 the inspiral becomes significantly more stable, broadly consistent with analytical expectations. This phase is not fully converged with respect to numerical resolution, and higher resolution simulations are expected to further increase its duration and stability. Although higher q systems show enhanced mass loss through the L2 and L3 Lagrange points, we find that circumbinary discs are more likely to form from fallback of bound envelope material. Fallback times are short, of order a few hundred years, and fallback radii lie well outside the binary, between 0.5 and 5 au, where discs are expected to spread efficiently through viscous torques. While high mass ratio systems produce wider post-interaction separations, these remain smaller than those observed. In contrast, fallback-formed discs have properties consistent with observed circumbinary discs.