# APOGEE [C/N] Abundances Across the Galaxy: Migration and Infall from Red   Giant Ages

**Authors:** Sten Hasselquist, Jon A. Holtzman, Matthew Shetrone, Jamie Tayar,, David H. Weinberg, Diane Feuillet, Katia Cunha, Marc H. Pinsonneault,, Jennifer A. Johnson, Jonathan Bird, Timothy C. Beers, Ricardo Schiavon, Ivan, Minchev, J. G. Fern\'andez-Trincado, D. A. Garc\'ia-Hern\'andez, Christian, Nitschelm, Olga Zamora

arXiv: 1812.05092 · 2019-02-13

## TL;DR

This study uses APOGEE data to analyze [C/N] abundance trends in red giant stars across the Milky Way, revealing insights into stellar ages, migration, and chemical evolution without a simple age-metallicity correlation.

## Contribution

It demonstrates how [C/N] ratios can be used to infer stellar ages and migration patterns across the Galaxy, challenging simple chemical evolution models.

## Key findings

- No anti-correlation between age and metallicity at any Galactic zone.
- Radial [C/N] gradient observed far from the Galactic plane.
- Older stars show a flatter metallicity gradient consistent with migration models.

## Abstract

We present [C/N]-[Fe/H] abundance trends from the SDSS-IV Apache Point Observatory Galactic Evolution Experiment (APOGEE) survey, Data Release 14 (DR14), for red giant branch stars across the Milky Way Galaxy (MW, 3 kpc $<$ R $<$ 15 kpc). The carbon-to-nitrogen ratio (often expressed as [C/N]) can indicate the mass of a red giant star, from which an age can be inferred. Using masses and ages derived by Martig et al., we demonstrate that we are able to interpret the DR14 [C/N]-[Fe/H] abundance distributions as trends in age-[Fe/H] space. Our results show that an anti-correlation between age and metallicity, which is predicted by simple chemical evolution models, is not present at any Galactic zone. Stars far from the plane ($|$Z$|$ $>$ 1 kpc) exhibit a radial gradient in [C/N] ($\sim$ $-$0.04 dex/kpc). The [C/N] dispersion increases toward the plane ($\sigma_{[C/N]}$ = 0.13 at $|$Z$|$ $>$ 1 kpc to $\sigma_{[C/N]}$ = 0.18 dex at $|$Z$|$ $<$ 0.5 kpc). We measure a disk metallicity gradient for the youngest stars (age $<$ 2.5 Gyr) of $-$0.060 dex/kpc from 6 kpc to 12 kpc, which is in agreement with the gradient found using young CoRoGEE stars by Anders et al. Older stars exhibit a flatter gradient ($-$0.016 dex/kpc), which is predicted by simulations in which stars migrate from their birth radii. We also find that radial migration is a plausible explanation for the observed upturn of the [C/N]-[Fe/H] abundance trends in the outer Galaxy, where the metal-rich stars are relatively enhanced in [C/N].

## Full text

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## Figures

13 figures with captions in the complete paper: https://tomesphere.com/paper/1812.05092/full.md

## References

85 references — full list in the complete paper: https://tomesphere.com/paper/1812.05092/full.md

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Source: https://tomesphere.com/paper/1812.05092