Five groups of red giants with distinct chemical composition in the globular cluster NGC 2808

TL;DR

This study analyzes the chemical compositions of 140 red giant stars in globular cluster NGC 2808, revealing five distinct populations with unique chemical signatures and high-temperature proton-capture processes.

Contribution

It provides a detailed homogeneous re-analysis of stellar abundances, uncovering five chemically distinct populations within NGC 2808, enhancing understanding of its complex stellar composition.

Findings

Five distinct stellar populations identified based on Na-O and Mg-Al anticorrelations.

Large Mg depletions and Si enhancements suggest high-temperature proton-captures.

Iron and alpha-elements show no intrinsic scatter across the sample.

Abstract

The chemical composition of multiple populations in the massive globular cluster (GC) NGC~2808 is addressed with the homogeneous abundance re-analysis of 140 red giant branch (RGB) stars. UVES spectra for 31 stars and GIRAFFE spectra for the other giants were analysed with the same procedures used for about 2500 giants in 23 GCs in our FLAMES survey, deriving abundances of Fe, O, Na, Mg, Si, Ca, Ti, Sc, Cr, Mn, and Ni. Iron, elements from alpha-capture, and in the Fe-group do not show intrinsic scatter. On our UVES scale the metallicity of NGC~2808 is [Fe/H]=-1.129+/-0.005+/-0.034$ (+/-statistical +/-systematic error) with sigma=0.030 (31 stars). Main features related to proton-capture elements are retrieved, but the improved statistics and the smaller associated internal errors allow to uncover five distinct groups of stars along the Na-O anticorrelation. We observe large depletions in Mg, anticorrelated with enhancements of Na and also Si, suggestive of unusually high temperatures for proton-captures. About 14% of our sample is formed by giants with solar or subsolar [Mg/Fe] ratios. Using the [Na/Mg] ratios we confirm the presence of five populations with different chemical composition, that we called P1, P2, I1, I2, and E in order of decreasing Mg and increasing Na abundances. Statistical tests show that the mean ratios in any pair of groups cannot be extracted from the same parent distribution. The overlap with the five populations recently detected from UV photometry is good but not perfect, confirming that more distinct components probably exist in this complex GC.