Carbon-Enhanced Metal-Poor Stars in the Inner and Outer Halo Components of the Milky Way

Abstract

(Abridged) Carbon-enhanced metal-poor (CEMP) stars in the halo components of the Milky Way are explored, based on accurate determinations of the carbon-to-iron ([C/Fe]) abundance ratios and kinematic quantities for over 30000 calibration stars from the Sloan Digital Sky Survey (SDSS). Using our present criterion that low-metallicity stars exhibiting [C/Fe] ratios ("carbonicity") in excess of [C/Fe] = +0.7 are considered CEMP stars, the global frequency of CEMP stars in the halo system for \ < -1.5 is 8%; for \ < -2.0 it is 12%; for \ <-2.5 it is 20%. We also confirm a significant increase in the level of carbon enrichment with declining metallicity, growing from <[C/Fe]> +1.0 at \ = -1.5 to <[C/Fe]> +1.7 at \ = -2.7. The nature of the carbonicity distribution function (CarDF) changes dramatically with increasing distance above the Galactic plane, |Z|. For |Z| < 5 kpc, relatively few CEMP stars are identified. For distances |Z| > 5 kpc, the CarDF exhibits a strong tail towards high values, up to [C/Fe] > +3.0. We also find a clear increase in the CEMP frequency with |Z|. For stars with -2.0 < [Fe/H] < -1.5, the frequency grows from 5% at |Z| 2 kpc to 10% at |Z| 10 kpc. For stars with [Fe/H] < -2.0, the frequency grows from 8% at |Z| 2 kpc to 25% at |Z| 10 kpc. For stars with -2.0 < [Fe/H] < -1.5, the mean carbonicity is <[C/Fe]> +1.0 for 0 kpc < |Z| < 10 kpc, with little dependence on |Z|; for [Fe/H] < -2.0, <[C/Fe]> +1.5, again roughly independent of |Z|.