The stellar velocity distribution function in the Milky Way galaxy

Abstract

The stellar velocity distribution function (DF) in the solar vicinity is re-examined using data from the SDSS APOGEE survey's DR16 and Gaia DR2. By exploiting APOGEE's ability to chemically discriminate with great reliability the thin disk, thick disk and (accreted) halo populations, we can, for the first time, derive the three-dimensional velocity DFs for these chemically-separated populations. We employ this smaller, but more data-rich APOGEE+ Gaia sample to build a data-driven model of the local stellar population velocity DFs, and use these as basis vectors for assessing the relative density proportions of these populations over 5 < R < 12 kpc, and -1.5 < z < 2.5 kpc range as derived from the larger, more complete (i.e., all-sky, magnitude-limited) Gaia database. We find that 81.9 3.1\% of the objects in the selected Gaia data-set are thin-disk stars, 16.6 3.2\% are thick-disk stars, and 1.5 0.1\% belong to the Milky Way stellar halo. We also find the local thick-to-thin-disk density normalization to be T(R)/t(R) = 2.1 0.2\%, a result consistent with, but determined in a completely different way than, typical starcount/density analyses. Using the same methodology, the local halo-to-disk density normalization is found to be H(R)/(T(R) + t(R)) = 1.2 0.6\%, a value that may be inflated due to chemical overlap of halo and metal-weak thick disk stars.