http://arxiv.org/abs/1905.08309
We investigate how the stellar and gas-phase He abundances evolve as functions of time within three simulated star-forming disc galaxies, characterised by different star formation histories. We make use of a cosmological chemodynamical simulation for galaxy formation and evolution, which includes star formation, as well as energy and chemical enrichment feedback from asymptotic giant branch stars, core-collapse supernovae, and Type Ia supernovae. The predicted relations between the He mass fraction, $Y$, and the metallicity, $Z$, in the interstellar medium of our simulated disc galaxies depend on the past galaxy star formation history. In particular, we find that $dY/dZ$ is not constant and evolves as a function of time, depending on the specific chemical element that we choose to trace $Z$, with $dY/dX_{\text{O}}$ and $dY/dX_{\text{C}}$ increasing as functions of time, and $dY/dX_{\text{N}}$ decreasing as a function of time. Interestingly, $dY/dX_{\text{C+N}}$ evolves very weakly, being always in the range $\approx[6.4,6.6]$. We predict negative radial gradients for the gas-phase He abundances in our simulated disc galaxies, due to the galaxy inside-out growth as a function of time, which gives rise to longer chemical enrichment time scales in the outer galaxy regions, where we find lower average values for $Y$ and $Z$. In order to calibrate the $Y$-$Z$ relation to assume in stellar models, we conclude that C, N, and C+N are better proxies for the metallicity than O, because they show steeper and less scattered relations in the interstellar medium at any epoch of the galaxy evolution.
F. Vincenzo, A. Miglio, C. Kobayashi, et. al.
Wed, 22 May 19
16/59
Comments: 9 pages, 12 figures
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