The dynamical fate of binary star clusters in the Galactic tidal field

TL;DR

This study uses N-body simulations and semi-analytic models to explore how binary star clusters evolve under the Galactic tidal field, revealing the importance of initial orientation and phase on their fate and merger outcomes.

Contribution

It introduces a semi-analytic model that accurately predicts the long-term evolution of binary star clusters, validated by N-body simulations, highlighting the impact of initial conditions on their dynamics.

Findings

Initial orientation and phase determine binary cluster evolution.

Binary clusters can merge, spiral-in, or oscillate before merging.

Merger ejects about 10% of stars into the Galactic field.

Abstract

Fragmentation and fission of giant molecular clouds occasionally results in a pair of gravitationally bound star clusters that orbit their mutual centre of mass for some time, under the influence of internal and external perturbations. We investigate the evolution of binary star clusters with different orbital configurations, with a particular focus on the Galactic tidal field. We carry out $N$-body simulations of evolving binary star clusters and compare our results with estimates from our semi-analytic model. The latter accounts for mass loss due to stellar evolution and two-body relaxation, and for evolution due to external tides. Using the semi-analytic model we predict the long-term evolution for a wide range of initial conditions. It accurately describes the global evolution of such systems, until the moment when a cluster merger is imminent. $N$-body simulations are used to test our semi-analytic model and also to study additional features of evolving binary clusters, such as the kinematics of stars, global cluster rotation, evaporation rates, and the cluster merger process. We find that the initial orientation of a binary star cluster with respect to the Galactic field, and also the initial orbital phase, are crucial for its fate. Depending on these properties, the binaries may experience orbital reversal, spiral-in, or vertical oscillation about the Galactic plane before they actually merge at $t\approx100$~Myr, and produce rotating star clusters with slightly higher evaporation rates. The merger process of a binary cluster induces an outburst that ejects $\sim10\%$ of the stellar members into the Galactic field.