Demographics of triple systems in dense star clusters

TL;DR

This paper investigates the formation and characteristics of stellar and compact-object triple systems in dense star clusters through simulations, highlighting their potential to produce various astrophysical transients and gravitational wave sources.

Contribution

It provides the first detailed demographic analysis of triples formed via binary-binary encounters in globular cluster simulations, linking cluster properties to triple formation.

Findings

Clusters typically form hundreds of triples with black holes in the inner binary.

Small virial radius clusters efficiently produce triples without black holes.

Tens of triples with luminous components are expected in typical globular clusters.

Abstract

Depending on the stellar type, more than $\sim 50$\% and $\sim 15\%$ of stars in the field have at least one and two stellar companions, respectively. Hierarchical systems can be assembled dynamically in dense star clusters, as a result of few-body encounters among stars and/or compact remnants in the cluster core. In this paper, we present the demographics of stellar and compact-object triples formed via binary--binary encounters in the \texttt{CMC Cluster Catalog}, a suite of cluster simulations with present-day properties representative of the globular clusters (GCs) observed in the Milky Way. We show how the initial properties of the host cluster set the typical orbital parameters and formation times of the formed triples. We find that a cluster typically assembles hundreds of triples with at least one black hole (BH) in the inner binary, while only clusters with sufficiently small virial radii are efficient in producing triples with no BHs, as a result of the BH-burning process. We show that a typical GC is expected to host tens of triples with at least one luminous component at present day. We discuss how the Lidov-Kozai mechanism can drive the inner binary of the formed triples to high eccentricities, whenever it takes place before the triple is dynamically reprocessed by encountering another cluster member. Some of these systems can reach sufficiently large eccentricities to form a variety of transients and sources, such as blue stragglers, X-ray binaries, Type Ia Supernovae, Thorne-Zytkow objects, and LIGO/Virgo sources.