Chemical Abundances in the Milky Way's Nuclear Stellar Disc

Abstract: The Nuclear Stellar Disc (NSD) is a rotating, disc-like structure in the Galactic Center, believed to have a distinct star formation. However, its formation history and evolutionary links to other structures in the Galactic Center remain uncertain. This study aims to present the first comprehensive chemical census of the NSD by deriving abundance trends for 18 elements in 9 M giants in the metallicity range of -1.0 <[Fe/H]< 0.5. By comparing these trends with those of other Galactic populations we seek to understand the chemical relationships between these structures. We obtained high-resolution H- and K-band spectra of NSD stars using the IGRINS spectrometer mounted on the Gemini South telescope. The giants were analyzed consistently with stars from a comparison populations to minimize systematic uncertainties. The abundance trends of NSD stars exhibit similarities with those of the inner-bulge and Nuclear Star Cluster (NSC) populations across a broad range of elements with different chemical evolution histories. The trends for 17 elements align closely with the local thick-disc behaviour at subsolar metallicities. At super-solar metallicities, most elements follow the NSC and inner-bulge trends. Sodium is the only element exhibiting a distinct trend, with enhanced abundances in the NSD and NSC compared to both thin-disc and inner-bulge stars. The chemical similarity suggests that the NSD likely shares an evolutionary history with the NSC and possibly the inner-disc sequence. Further studies are required to determine potential evolutionary links to Liller 1 and metal-rich globular clusters. We find no evidence of typical globular cluster abundance signatures in our NSD stars with subsolar metallicities. Our study demonstrates the feasibility of obtaining high-quality abundance data even in highly dust-obscured regions of the Milky Way, paving the way for future surveys.