Effects of massive central objects on the degree of energy equipartition of globular clusters

TL;DR

This study investigates how the presence of black hole systems in globular clusters affects their energy distribution, revealing signatures that could help identify such systems in observations.

Contribution

First systematic analysis of the impact of stellar-mass black holes and IMBHs on energy equipartition in globular clusters using Monte Carlo simulations.

Findings

Black hole systems can halt energy equipartition in cluster centers.

IMBH effects depend on their mass fraction and co-evolution with the cluster.

Some observed clusters show signatures consistent with hosting black hole systems.

Abstract

We present an analysis of the degree of energy equipartition in a sample of 101 Monte Carlo numerical simulations of globular clusters (GCs) hosting either a system of stellar-mass black holes (BHS), an intermediate-mass black hole (IMBH) or neither of them. For the first time, we systematically explore the signatures that the presence of BHS or IMBHs produces on the degree of energy equipartition and if these signatures could be found in current observations. We show that a BHS can halt the evolution towards energy equipartition in the cluster centre. We also show that this effect grows stronger with the number of stellar-mass black holes in the GC. The signatures introduced by IMBHs depend on how dominant their masses are to the GCs and for how long the IMBH has co-evolved with its host GCs. IMBHs with a mass fraction below 2% of the cluster mass produce a similar dynamical effect to BHS, halting the energy equipartition evolution. IMBHs with a mass fraction larger than 2% can produce an inversion of the observed mass-dependency of the velocity dispersion, where the velocity dispersion grows with mass. We compare our results with observations of Galactic GCs and show that the observed range of the degree of energy equipartition in real clusters is consistent with that found in our analysis. In particular, we show that some Galactic GCs fall within the anomalous behaviour expected for systems hosting a BHS or an IMBH and are promising candidates for further dynamical analysis.