True Unicorns and False Positives: Simulated Probabilities of Dark Massive Companions to Bright Stars

TL;DR

This study uses binary evolution simulations to assess the likelihood that bright stars with dark companions are true compact object binaries, revealing factors that influence their identification and evolution.

Contribution

It introduces a probabilistic framework using COSMIC simulations to distinguish true compact object binaries from false positives among candidate systems.

Findings

Main sequence stars have higher true unicorn probability than red giants.

Top-heavy initial mass functions increase the likelihood of true unicorns.

Most true unicorns are found at orbital periods less than 100 days.

Abstract

Many compact objects (black holes and neutron stars) exist in binaries. These binaries are normally discovered through their interactions, either from accretion as an X-ray binary or collisions as a gravitational wave source. However, the majority of compact objects in binaries should be non-interacting. Recently proposed discoveries have used radial velocities of a bright star (main sequence or evolved) that are indicative of a massive but dark companion, which is inferred to be a compact object. Unfortunately, this burgeoning new field has been hindered by false positives, including the ``Unicorn'' (V723 Mon) which was initially believed to be a red giant/black hole binary before being refuted. In this work, we investigate the evolution of stellar binary populations over time, using the binary evolution code COSMIC to simulate binary populations and determine the probability of a candidate object being either a ``true Unicorn'' (actual compact objects in binaries) or a false positive. We find that main sequence stars have a higher true Unicorn probability than red giants or naked helium stars (an exposed core of an evolved star), particularly if the companion is more massive and is >3 times less luminous than the MS star. We also find that a top-heavy initial mass function raises the true Unicorn probability further, that super-solar metallicity reduces the probability, and that most true Unicorns are found at periods <100 days. Finally, we find that a significant fraction of true Unicorns do not evolve into x-ray binaries during the age of the universe.