The Stellar Metallicity Distribution Function of the Galactic Halo from SDSS Photometry

TL;DR

This study analyzes the metallicity distribution of the Galactic halo using SDSS photometry, revealing evidence for multiple stellar populations with distinct kinematic and chemical properties, challenging single-population models.

Contribution

It provides a calibrated photometric method to estimate stellar metallicities and uncovers a dual-component structure in the Galactic halo based on metallicity and kinematic data.

Findings

Halo metallicity distribution matches local halo stars.

Stars with retrograde motion are more metal-poor.

Halo comprises at least two populations with different metallicities.

Abstract

We explore the stellar metallicity distribution function of the Galactic halo based on SDSS ugriz photometry. A set of stellar isochrones is calibrated using observations of several star clusters and validated by comparisons with medium-resolution spectroscopic values over a wide range of metal abundance. We estimate distances and metallicities for individual main-sequence stars in the multiply scanned SDSS Stripe 82, at heliocentric distances in the range 5 - 8 kpc and |b| > 35 deg, and find that the in situ photometric metallicity distribution has a shape that matches that of the kinematically-selected local halo stars from Ryan & Norris. We also examine independent kinematic information from proper-motion measurements for high Galactic latitude stars in our sample. We find that stars with retrograde rotation in the rest frame of the Galaxy are generally more metal poor than those exhibiting prograde rotation, which is consistent with earlier arguments by Carollo et al. that the halo system comprises at least two spatially overlapping components with differing metallicity, kinematics, and spatial distributions. The observed photometric metallicity distribution and that of Ryan & Norris can be described by a simple chemical evolution model by Hartwick (or by a single Gaussian distribution); however, the suggestive metallicity-kinematic correlation contradicts the basic assumption in this model that the Milky Way halo consists primarily of a single stellar population. When the observed metallicity distribution is deconvolved using two Gaussian components with peaks at [Fe/H] ~ -1.7 and -2.3, the metal-poor component accounts for ~20% - 35% of the entire halo population in this distance range.