CECILIA: Direct O, N, S, and Ar Abundances in Q2343-D40, a Galaxy at $z\sim$3

Noah S. J. Rogers, Allison L. Strom, Gwen C. Rudie, Ryan F. Trainor, Menelaos Raptis, Caroline von Raesfeld

Published 2023-12-13Version 1

Measurements of chemical abundances in high-$z$ star-forming (SF) galaxies place important constraints on the enrichment history of massive stars and the physical conditions in the early universe. JWST is beginning to enable direct chemical abundance measurements in galaxies at $z$$>$2 via the detection of the faint T$_e$-sensitive auroral line [O III]$\lambda$4363. However, direct abundances of other elements (e.g., S and Ar) in high-$z$ galaxies remain unconstrained due to a lack of T$_e$ data and wavelength coverage. Here, we present multiple direct abundances in D40, a galaxy at $z$$\sim$3 observed with JWST/NIRSpec as part of the CECILIA program. We report the first simultaneous measurement of T$_e$[O III] and T$_e$[S III] in a high-$z$ galaxy, finding good agreement with the temperature trends in local SF systems and photoionization models. We measure a gas-phase metallicity of 12+log(O/H) $=8.16\pm0.05$ dex, and an N/O abundance indicative of primary nucleosynthesis. The S/O abundance in D40 is slightly sub-solar but consistent with local H II regions. In contrast, the log(Ar/O) in D40 is $-$2.71$\pm$0.09 dex, sub-solar by $>$2$\sigma$. The [Ar III]$\lambda$7135 intensities of D40 and other CECILIA galaxies are similar to those of local SF systems with Ar-deficient interstellar media, suggesting that low gas-phase Ar abundance is common in high-$z$ galaxies. Recent nucleosynthesis models find that Ar is produced in Type Ia supernovae: if low Ar/O is consistently observed in high-$z$ SF galaxies, it would provide further observational evidence that early galaxies are enriched primarily by core-collapse supernovae, which produce enhanced O relative to Ar and Fe.