Abundance ratios in GALAH DR2 and their implications for nucleosynthesis

Emily Griffith, Jennifer A. Johnson, David H. Weinberg

Published 2019-08-16Version 1

Using a sample of 70 924 stars from the second data release of the GALAH optical spectroscopic survey, we construct median sequences of [X/Mg] vs. [Mg/H] for 21 elements, separating the low-Ia (high-$\alpha$) and high-Ia (low-$\alpha$) stellar populations based on cuts in [Mg/Fe]. Previous work with the near-IR APOGEE survey has shown that such sequences are nearly independent of location in the Galactic disk, which implies that they are determined by stellar nucleosynthesis yields with little sensitivity to other aspects of chemical evolution. The separation between the low-Ia and high-Ia [X/Mg] sequences indicates the relative importance of prompt and delayed enrichment mechanisms (e.g., core collapse supernovae vs. SNIa or AGB stars), while the slopes of the sequences indicate metallicity dependence of the corresponding yields. GALAH and APOGEE measurements agree fairly well for some of the elements they have in common (Si, Mn, Cr, Fe, Ni), but they differ in sequence separation or metallicity trends for others (O, Ca, Na, Al, K, V, Co). GALAH offers access to nine new elements. We infer that about $75\%$ of solar C comes from core collapse supernovae and $25\%$ from delayed mechanisms. We find core collapse fractions of $60-80\%$ for the Fe-peak elements Sc, Ti, Cu, and Zn, with strong metallicity dependence of the core collapse Cu yield. For the neutron capture elements Y, Ba, and La, we infer large delayed contributions with, non-monotonic metallicity dependence. The separation of the [Eu/Mg] sequences implies that at least $\sim30\%$ of Eu enrichment is significantly delayed with respect to star formation. We compare our results to predictions of several supernova and AGB yield models; C, Na, K, Mn, and Ca all show discrepancies with one or more models that could make them useful diagnostics of nucleosynthesis physics.