# Constraints on the distance moduli, helium and metal abundances, and   ages of globular clusters from their RR Lyrae and non-variable   horizontal-branch stars. II. Multiple stellar populations in 47Tuc, M3, and   M13

**Authors:** Pavel Denissenkov (University of Victoria), Don A. VandenBerg, (University of Victoria), Grzegorz Kopacki (University of Wroclaw), and Jason, W. Ferguson (Wichita State University)

arXiv: 1706.05454 · 2017-11-15

## TL;DR

This study uses advanced stellar evolution models to analyze multiple stellar populations in globular clusters 47Tuc, M3, and M13, providing insights into their compositions, ages, and the role of helium variation.

## Contribution

It introduces new HB models with gravitational settling and alpha-enhanced metals, successfully reproducing observed HB features and stellar populations in three globular clusters.

## Key findings

- Good fit of models to 47Tuc HB with helium variation.
- Estimated ages of 13.0 Gyr for 47Tuc, 12.6 Gyr for M3, and 12.9 Gyr for M13.
- Mass loss and helium variation are key second parameters.

## Abstract

We present a new set of horizontal-branch (HB) models computed with the MESA stellar evolution code. The models adopt $\alpha$-enhanced \cite{ags09} metals mixtures and include the gravitational settling of He. They are used in our HB population synthesis tool to generate theoretical distributions of HB stars in order to describe the multiple stellar populations in the globular clusters 47Tuc, M3, and M13. The observed HB in 47Tuc is reproduced very well by our simulations for [Fe/H] $= -0.70$ and [$\alpha$/Fe] $= +0.4$ if the initial helium mass fraction varies by $\Delta Y_0 \sim 0.03$ and approximately 21%, 37%, and 42% of the stars have $Y_0 = 0.257$, 0.270, and 0.287, respectively. These simulations yield $(m-M)_V = 13.27$, implying an age near 13.0 Gyr. In the case of M3 and M13, our synthetic HBs for [Fe/H] $= -1.55$ and [$\alpha$/Fe] $= 0.4$ match the observed ones quite well if M3 has $\Delta Y_0 \sim 0.01$ and $(m-M)_V = 15.02$, resulting in an age of 12.6 Gyr, whereas M13 has $\Delta Y_0 \sim 0.08$ and $(m-M)_V = 14.42$, implying an age of 12.9 Gyr. Mass loss during giant-branch evolution and $\Delta Y_0$ appear to be the primary second parameters for M3 and M13. New observations for 7 of the 9 known RR Lyrae in M13 are also reported. Surprisingly, periods predicted for the $c$-type variables tend to be too high (by up to $\sim 0.1$~d).

## Full text

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## Figures

23 figures with captions in the complete paper: https://tomesphere.com/paper/1706.05454/full.md

## References

161 references — full list in the complete paper: https://tomesphere.com/paper/1706.05454/full.md

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Source: https://tomesphere.com/paper/1706.05454