Lund University Publications

Supergiant GCIRS 22 in the Milky Way nuclear star cluster : Revised alpha abundances

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Thorsbro, B. ^LU ; Khalidy, S. ; Rich, R. M. ; Schultheis, M. ; Taniguchi, D. ; Amarsi, A. M. ; Kordopatis, G. ; Nandakumar, G. ^LU ; Nishiyama, S. and Ryde, N. ^LU

Abstract

Context. The chemical abundances of alpha elements in Galactic Centre (GC) supergiants provide key insights into the chemical enrichment and star formation history of the Milky Way’s nuclear star cluster. Previous studies have reported enhanced alpha-element abundances, which raises questions about the chemical evolution of this unique region. Aims. We aim to reassess the alpha-element abundances in the GC supergiant GCIRS 22 using updated spectral modelling and non-local thermodynamic equilibrium (NLTE) corrections to resolve discrepancies from earlier abundance analyses. Methods. We analysed high-resolution near-infrared spectra of GCIRS 22 using contemporary line lists and precise stellar parameters derived from scandium line... (More)

Context. The chemical abundances of alpha elements in Galactic Centre (GC) supergiants provide key insights into the chemical enrichment and star formation history of the Milky Way’s nuclear star cluster. Previous studies have reported enhanced alpha-element abundances, which raises questions about the chemical evolution of this unique region. Aims. We aim to reassess the alpha-element abundances in the GC supergiant GCIRS 22 using updated spectral modelling and non-local thermodynamic equilibrium (NLTE) corrections to resolve discrepancies from earlier abundance analyses. Methods. We analysed high-resolution near-infrared spectra of GCIRS 22 using contemporary line lists and precise stellar parameters derived from scandium line diagnostics. We applied comprehensive NLTE corrections to accurately determine the abundances of silicon and calcium. Results. Our analysis reveals solar-scale alpha abundances ([Ca/Fe] = 0.06 ± 0.07; [Si/Fe] = than −0.08 ± 0.20) for GCIRS 22, which are significantly lower than previous local thermodynamic equilibrium (LTE) based findings. NLTE corrections reduce the calcium abundance by approximately 0.3 dex compared to LTE estimates; this aligns our results with recent studies and highlights the importance of accurate NLTE modelling. Conclusions. The solar-scale alpha-element abundances observed in GCIRS 22 suggest that recent star formation in the region has not been dominated by Type II supernovae, such as those expected from a recent starburst. Our findings support a scenario of episodic star formation, characterized by intermittent bursts separated by extended quiescent phases, or potentially driven by gas inflows from the inner disc, funnelled by the Galactic bar. Future comprehensive NLTE studies of additional GC stars will be essential for refining our understanding of the region’s chemical evolution and star formation history.

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