Chemical Abundances in the Nuclear Star Cluster of the Milky Way: Alpha-element Trends and Their Similarities with the Inner Bulge

Chemical characterization of the Galactic center is essential for understanding its formation and structural evolution. Trends of alpha ( α ) elements, such as magnesium, silicon, and calcium, serve as powerful diagnostic tools, offering insights into star formation rates and gas-infall history. How...

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Published in:The Astrophysical journal 2025-02, Vol.979 (2), p.174
Main Authors: Ryde, Nils, Nandakumar, Govind, Schultheis, Mathias, Kordopatis, Georges, di Matteo, Paola, Haywood, Misha, Schödel, Rainer, Nogueras-Lara, Francisco, Rich, R. Michael, Thorsbro, Brian, Mace, Gregory N., Agertz, Oscar, Amarsi, Anish M., Kocher, Jessica, Molero, Marta, Orglia, Livia, Pagnini, Giulia, Spitoni, Emanuele
Format: Article
Language:English
Subjects:
Chemical abundances
Galactic archaeology
Galactic center
High resolution spectroscopy
Late-type giant stars
M giant stars
Near infrared astronomy
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Summary:Chemical characterization of the Galactic center is essential for understanding its formation and structural evolution. Trends of alpha ( α ) elements, such as magnesium, silicon, and calcium, serve as powerful diagnostic tools, offering insights into star formation rates and gas-infall history. However, high extinction has previously hindered such studies. In this study, we present a detailed chemical abundance analysis of M giants in the Milky Way's nuclear star cluster (NSC), focusing on α -element trends with metallicity. High-resolution, near-infrared spectra were obtained using the Immersion GRating INfrared Spectrograph on the Gemini South telescope for nine M giants. Careful selection of spectral lines, based on a solar-neighborhood control sample of 50 M giants, was implemented to minimize systematic uncertainties. Our findings show enhanced α -element abundances in the predominantly metal-rich NSC stars, consistent with trends in the inner bulge. The NSC stars follow the high-[ α /Fe] envelope seen in the solar vicinity's metal-rich population, indicating a high star formation rate. The α -element trends decrease with increasing metallicity, also at the highest metallicities. Our results suggest the NSC population likely shares a similar evolutionary history with the inner bulge, challenging the idea of a recent dominant star formation burst. This connection between the NSC and the inner-disk sequence suggests that the chemical properties of extragalactic NSCs of Milky Way–type galaxies could serve as a proxy for understanding the host galaxies’ evolutionary processes.
ISSN:0004-637X
1538-4357
DOI:10.3847/1538-4357/ad9b2b