Abstract
Context.The possibility of identifying co-natal stars that have dispersed into the Galactic disc based on chemistry alone is called strong chemical tagging. It has been debated for a long time whether this is indeed feasible; it holds the promise of reconstructing the detailed star formation history of a large fraction of stars in the Galactic disc.Aims.We investigate the feasibility of strong chemical tagging using known member stars of open clusters.Methods.We analysed the largest sample of cluster members that have been homogeneously characterised with high-resolution differential abundances for 16 different elements. We also investigated the possibility of finding the known clusters in the APOGEE DR16 red clump sample with 18 chemical species. For both purposes, we used a clustering algorithm and an unsupervised dimensionality reduction technique to blindly search for groups of stars in chemical space.Results.Even if the internal coherence of the stellar abundances in the same cluster is high, typically 0.03 dex, the overlap in the chemical signatures of the clusters is large. In the sample with the highest precision and no field stars, we only recover 9 out of the 31 analysed clusters at a 40% threshold of homogeneity and precision. This ratio slightly increases when we only use clusters with 7 or more members. In the APOGEE sample, field stars are present along with four populated clusters. In this case, only one of the open clusters was moderately recovered.Conclusions.In our best-case scenario, more than 70% of the groups of stars are in fact statistical groups that contain stars belonging to different real clusters. This indicates that the chances of recovering the majority of birth clusters dissolved in the field are slim, even with the most advanced clustering techniques. We show that different stellar birth sites can have overlapping chemical signatures, even when high-resolution abundances of many different nucleosynthesis channels are used. This is substantial evidence against the possibility of strong chemical tagging. However, we can hope to recover some particular birth clusters that stand out at the edges of the chemical distribution.
Highlights
The chemical tagging technique (Freeman & Bland-Hawthorn 2002) consists of grouping stars with similar chemical signatures
It has been debated for a long time whether this is feasible; it holds the promise of reconstructing the detailed star formation history of a large fraction of stars in the Galactic disc
We investigate the feasibility of strong chemical tagging using known member stars of open clusters
Summary
The chemical tagging technique (Freeman & Bland-Hawthorn 2002) consists of grouping stars with similar chemical signatures. The highly dissipative nature of the dynamical interactions in the disc prevents us from using the observed kinematics of the individual stars to track them back to their common formation sites Stars preserve their birth chemical information in their stellar atmospheres for most chemical elements. Assuming a uniform composition of the parent molecular cloud, we can hope to associate individual stars with their birth clusters using chemistry alone This is the idea behind strong chemical tagging, and it has been one of the motivations of several spectroscopic surveys, including APOGEE (Majewski et al 2017), GALAH (De Silva et al 2015) or the Gaia-ESO survey (Randich et al 2013; Gilmore et al 2012). Known open clusters (OCs) are the perfect testbed for studying the possibilities of strong chemical tagging because they are the only example of birth clusters that have survived dynamical effects and remain gravitationally bound today
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