Stellar triples with chemically homogeneously evolving inner binaries

TL;DR

This study explores the evolution of hierarchical stellar triples with chemically homogeneous inner binaries, revealing their potential to form gravitational-wave sources and undergo unique merger events influenced by tertiary stars and ZLK oscillations.

Contribution

It introduces a comprehensive analysis of CHE triples using the TRES code, highlighting the role of tertiaries and ZLK oscillations in their evolution and GW source formation.

Findings

Approximately 24-30% of CHE triples form GW sources.

Tertiary stars significantly influence the evolution of CHE binaries.

ZLK oscillations can cause eccentric mergers and binary formation.

Abstract

Observations suggest that massive stellar triples are common. However, their evolution is not yet fully understood. We investigate the evolution of hierarchical triples in which the stars of the inner binary experience chemically homogeneous evolution (CHE), particularly to understand the role of the tertiary star in the formation of gravitational-wave (GW) sources. We use the triple-star rapid population synthesis code TRES to determine the evolution of these systems at two representative metallicities: $Z = 0.005$ and $Z = 0.0005$. About half of all triples harbouring a CHE inner binary (CHE triples) experience tertiary mass transfer (TMT) episodes, an event which is rare for classically evolving stars. In the majority of TMT episodes, the inner binary consists of two main-sequence stars (58-60 per cent) or two black holes (BHs, 24-31 per cent). Additionally, we explore the role of von Zeipel-Lidov-Kozai (ZLK) oscillations for CHE triples. ZLK oscillations can result in eccentric stellar mergers or lead to the formation of eccentric compact binaries in systems with initial outer pericenters smaller than $\sim$ 1200 $R_{\odot}$. Approximately 24-30 per cent of CHE triples form GW sources, and in 31 per cent of these, the tertiary star plays a significant role and leads to configurations that are not predicted for isolated binaries. We conclude that the evolution of CHE binaries can be affected by a close tertiary companion, resulting in astronomical transients such as BH-BH binaries that merge via GW emission orders of magnitude faster than their isolated binary counterparts and tertiary-driven massive stellar mergers.