Contact tracing of binary stars: Pathways to stellar mergers

TL;DR

This study uses extensive binary evolution models to identify pathways leading to contact and mergers in binary stars, revealing the conditions and likelihoods of such events and their implications for stellar phenomena.

Contribution

It provides a detailed analysis of initial binary configurations that lead to contact and mergers, incorporating rotation and tides, and offers new insights into the mechanisms and probabilities of stellar mergers.

Findings

At least 40% of mass-transferring binaries with primary masses 5-20 M_sun enter contact.

Over 12% and 19% of these binaries are likely to merge or undergo classical CE phases.

Contact binaries are predominantly observed with mass ratio q > 0.5, consistent with model predictions.

Abstract

Stellar mergers lead to diverse phenomena: rejuvenated blue stragglers, magnetised and peculiar stars, transients and nebulae. Using a grid of about 6000 detailed 1D binary evolution models (initial component masses of 0.5-20$\,\text{M}_{\odot}$ at solar metallicity), we investigate which initial binary-star configurations lead to contact and classical common-envelope (CE) phases and assess the likelihood of a subsequent merger. Considering rotation and tides, we identify five mechanisms leading to contact and mergers: runaway mass transfer, $\text{L}_{2}$-overflow, accretor expansion, tidally-driven orbital decay, and non-conservative mass transfer. At least 40% of mass-transferring binaries with initial primary masses of 5-20$\,\text{M}_{\odot}$ enter contact, with >12% and >19% likely merging and evolving into a classical CE phase, respectively. Classical CE evolution occurs in late Case-B and Case-C binaries for initial mass ratios $q_{\text{i}}$ < 0.15-0.35, stable mass transfer for larger $q_{\text{i}}$. Early Case-B binaries enter contact for $q_{\text{i}}$ < 0.15-0.35 and in initially wider Case-A binaries, this occurs for $q_{\text{i}}$ < 0.35. All initially closest Case-A systems form contact binaries. We predict that binaries entering contact with $q$ < 0.5 merge or detach on a thermal timescale, while those formed with $q$ > 0.5 lead to long-lived contact phases. The fact that contact binaries are almost exclusively observed with $q$ > 0.5 confirms our expectations. Our contact, merger and classical CE incidences are lower limits because the mass transfer in our models is non-conservative. In most binaries, the non-accreted mass cannot be ejected and may settle in disks or lead to contact phases and mergers. Overall, contact binaries are a frequent and fascinating result of binary mass transfer of which the exact outcomes still remain to be understood and explored further.