Helium in first and second-generation stars in Globular Clusters from spectroscopy of red giants

TL;DR

This study analyzes the helium content in different stellar generations within globular clusters using spectroscopy of red giants, revealing measurable differences in helium abundance and related properties among populations.

Contribution

It provides detailed measurements of helium variations among stellar populations in globular clusters and compares these with stellar models, enhancing understanding of star formation history.

Findings

Helium abundance varies between stellar generations by about 0.05-0.19 in Y.

Differences are detectable in temperature, luminosity, and chemical composition.

NGC2808 shows clear separation of multiple populations on various evolutionary stages.

Abstract

(abridged) Recent spectroscopic and photometric observations show the existence of various generations of stars in GCs, differing in the abundances of products of H-burning at high temperatures (the main final product being He). It is important to study the connections between stars properties and He content. We consider here the about 1400 stars on the Red Giant Branch (RGB) observed with FLAMES@VLT in 19 Galactic GCs, part of out Na-O anticorrelation projet. Stars with different He are expected to have different temperatures (i.e. colours), slightly different [Fe/H], and different luminosity levels of the RGB bump. All these differences are small, but our study has the necessary precision, good statistics, and homogeneity to detect them. We also computed suitable sets of stellar models (BaSTI) for various assumptions about the initial helium content. Differences in observable quantities that can be attributed to variations in He content are generally detectable between stars of the Primordial (P, first-generation) and Extreme (E, second-generation) populations, but not between the Primordial and Intermediate ones (I). The only exception (differences are significant also between P and I populations) is NGC2808, where three populations are clearly separated also on the Main Sequence and the Horizontal Branch. The average enhancement in the He mass fraction Y between P and E stars is about 0.05-0.11, depending on the assumptions. The differences in Y, for NGC2808 alone, are about 0.11-0.14 between P and I stars, and about 0.15-0.19 between P and E stars, again depending on the assumptions. The RGB bump luminosity of first and second-generation stars has different levels; the implied Y difference is more difficult to quantify, but is in agreement with the other determinations.