# Correlation Between Mass Segregation and Structural Concentration in   Relaxed Stellar Clusters

**Authors:** Ruggero de Vita, Michele Trenti, Morgan MacLeod

arXiv: 1903.07619 · 2019-03-27

## TL;DR

This study reveals a robust linear correlation between mass segregation and structural concentration in relaxed stellar clusters, enabling easier observational assessment of their dynamical state and dark remnants.

## Contribution

It introduces a new, measurable relation between mass segregation and concentration index using N-body simulations, applicable without resolving individual low-mass stars.

## Key findings

- A tight linear relation between mass segregation and concentration index.
- The relation is robust across various initial conditions and cluster ages.
- Potential for a new observational tool to study cluster dynamics and dark remnants.

## Abstract

The level of mass segregation in the core of globular clusters has been previously proposed as a potential indicator of the dynamical constituents of the system, such as presence of a significant population of stellar-mass black holes (BHs), or even a central intermediate-mass black hole (IMBH). However, its measurement is limited to clusters with high-quality Hubble Space Telescope data. Thanks to a set of state-of-the-art direct N-body simulations with up to 200k particles inclusive of stellar evolution, primordial binaries, and varying BH/neutron stars, we highlight for the first time the existence of a clear and tight linear relation between the degree of mass segregation and the cluster structural concentration index. The latter is defined as the ratio of the radii containing 5% and 50% of the integrated light ($R_5/R_\mathrm{50}$), making it robustly measurable without the need to individually resolve low-mass stars. Our simulations indicate that given $R_5/R_\mathrm{50}$, the mass segregation $\Delta m$ (defined as the difference in main sequence median mass between center and half-light radius) is expressed as $\Delta m/M_\odot = -1.166 R_5/R_\mathrm{h} + 0.3246$, with a root-mean-square error of $0.0148$. In addition, we can explain its physical origin and the values of the fitted parameters through basic analytical modeling. Such correlation is remarkably robust against a variety of initial conditions (including presence of primordial binaries and IMBHs) and cluster ages, with a slight dependence in best-fit parameters on the prescriptions used to measure the quantities involved. Therefore, this study highlights the potential to develop a new observational tool to gain insight on the dynamical status of globular clusters and on its dark remnants.

## Full text

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## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/1903.07619/full.md

## References

61 references — full list in the complete paper: https://tomesphere.com/paper/1903.07619/full.md

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Source: https://tomesphere.com/paper/1903.07619