The stellar velocity distribution function in the Milky Way galaxy

TL;DR

This study uses APOGEE and Gaia data to derive the three-dimensional velocity distribution functions for different stellar populations in the Milky Way, providing new insights into their relative densities and kinematic properties.

Contribution

It presents the first data-driven model of local stellar velocity distribution functions for chemically-separated populations using APOGEE and Gaia data.

Findings

81.9% of stars are thin-disk stars

16.6% are thick-disk stars

1.5% belong to the stellar halo

Abstract

The stellar velocity distribution function (DF) in the solar vicinity is re-examined using data from the SDSS APOGEE survey's DR16 and \emph{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+{\it Gaia} sample to build a \emph{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) {\it Gaia} database. We find that 81.9 $\pm$ 3.1$\%$ of the objects in the selected \emph{Gaia} data-set are thin-disk stars, 16.6 $\pm$ 3.2$\%$ are thick-disk stars, and 1.5 $\pm$ 0.1$\%$ belong to the Milky Way stellar halo. We also find the local thick-to-thin-disk density normalization to be $\rho_{T}(R_{\odot})$/$\rho_{t}(R_{\odot})$ = 2.1 $\pm$ 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 $\rho_{H}(R_{\odot})$/($\rho_{T}(R_{\odot})$ + $\rho_{t}(R_{\odot})$) = 1.2 $\pm$ 0.6$\%$, a value that may be inflated due to chemical overlap of halo and metal-weak thick disk stars.