Abstract
We report the serendipitous discovery of a nitrogen-rich, mildly metal-poor ([Fe/H] = −1.08) giant star in a single-lined spectroscopic binary system found in the SDSS-IV Apache Point Observatory Galactic Evolution Experiment (APOGEE-2) survey, Data Release 14 (DR14). Previous work has assumed that two percent of halo giants with unusual elemental abundances have been evaporated from globular clusters, but other origins for their abundance signatures, including binary mass transfer, must also be explored. We present the results of an abundance reanalysis of the APOGEE-2 high-resolution near-infrared spectrum of 2M12451043+1217401 with the Brussels Automatic Stellar Parameter (BACCHUS) automated spectral analysis code. We manually re-derive the main element families, namely light elements (C, N), elements (O, Mg, Si), the iron-peak element (Fe), s-process element (Ce), and light odd-Z element (Al). Our analysis confirms the N-rich nature of 2M12451043+1217401, which has a [N/Fe] ratio of +0.69, and shows that the abundances of C and Al are slightly discrepant from those of a typical mildly metal-poor red giant branch star, but exhibit Mg, Si, O and s-process abundances (Ce) of typical field stars. We also detect a particularly large variability in the radial velocity of this star over the period of the APOGEE-2 observations; the most likely orbit fit to the radial velocity data has a period of 730.89 ± 106.86 days, a velocity semi-amplitude of 9.92 ± 0.14 km s−1, and an eccentricity of ∼0.1276 ± 0.1174. These data support the hypothesis of a binary companion, which has probably been polluted by a now-extinct asymptotic giant branch star.
Highlights
It is clear that stellar populations with distinctive light-element abundance patterns (Bastian & Lardo 2018; Fernández-Trincado et al 2019a) are extremely common in globular clusters (GCs), while metal-poor stars ([Fe/H] − 0.7) characterized by enhanced N ([N/Fe] +0.5) and depleted C ([C/Fe] +0.15) are rarely found in the field (Johnson et al 2007; Martell et al 2011; Carollo et al 2013)
red giant branch (RGB)/GCs stars could be the key players in the pollution of 12C14N via RHB/GCs a slow stellar wind that has polluted the RGB, and their eAGB/GCs atmospheric chemistry reflects some of the yields from an asymptotic giant branch (AGB) star
We communicate the serendipitous discovery of an unusual red giant star, which shows significantly enhanced [N/Fe] among metal-poor field stars
Summary
It is clear that stellar populations with distinctive light-element abundance patterns (Bastian & Lardo 2018; Fernández-Trincado et al 2019a) are extremely common in globular clusters (GCs), while metal-poor stars ([Fe/H] − 0.7) characterized by enhanced N ([N/Fe] +0.5) and depleted C ([C/Fe] +0.15) are rarely found in the field (Johnson et al 2007; Martell et al 2011; Carollo et al 2013). The new object associated with 2M12451043+1217401 is a nitrogen-enhanced and carbon-depleted metal-poor star with abundances of Al and Mg that are mildly discrepant from those of normal red giant branch (RGB) stars We hypothesize that this star is likely to be an example of the result of mass transfer from a binary companion, which is in the white dwarf stage of stellar evolution. In addition to those literature values, we systematically synthesized every element and line of 2M12451043+1217401 at high spectral resolution to compare with the Payne and ASPCAP determinations. This full set of abundance is the basis of our comparison with the literature values
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