Variations in α-element Ratios Trace the Chemical Evolution of the Disk
It is well established that the chemical structure of the Milky Way exhibits a bimodality with respect to the α -enhancement of stars at a given [Fe/H]. This has been studied largely based on a bulk α abundance, computed as a summary of several individual α -elements. Inspired by the expected subtle...
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Published in | The Astrophysical journal Vol. 883; no. 1; p. 34 |
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Main Authors | , , , , |
Format | Journal Article |
Language | English |
Published |
Philadelphia
IOP Publishing
20.09.2019
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Subjects | |
Online Access | Get full text |
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Summary: | It is well established that the chemical structure of the Milky Way exhibits a bimodality with respect to the
α
-enhancement of stars at a given [Fe/H]. This has been studied largely based on a bulk
α
abundance, computed as a summary of several individual
α
-elements. Inspired by the expected subtle differences in their nucleosynthetic origins, here we probe the higher level of granularity encoded in the inter-family [Mg/Si] abundance ratio. Using a large sample of stars with
APOGEE
abundance measurements, we first demonstrate that there is additional information in this ratio beyond what is already apparent in [
α
/Fe] and [Fe/H] alone. We then consider
Gaia
astrometry and stellar age estimates to empirically characterize the relationships between [Mg/Si] and various stellar properties. We find small but significant trends between this ratio and
α
-enhancement, age, [Fe/H], location in the Galaxy, and orbital actions. To connect these observed [Mg/Si] variations to a physical origin, we attempt to predict the Mg and Si abundances of stars with the galactic chemical evolution model
Chempy
. We find that we are unable to reproduce abundances for the stars that we fit, which highlights tensions between the yield tables, the chemical evolution model, and the data. We conclude that a more data-driven approach to nucleosynthetic yield tables and chemical evolution modeling is necessary to maximize insights from large spectroscopic surveys. |
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ISSN: | 0004-637X 1538-4357 |
DOI: | 10.3847/1538-4357/ab39e5 |