Galactic Stellar Populations from Photometric Metallicity Distribution Functions

Abstract

Based on Sloan Digital Sky Survey (SDSS) photometric data, Gu developed a new Monte-Carlo-based method for estimating the stellar metallicity distribution functions (MDFs). This method enables a more reliable determination of MDFs compared with the conventional polynomial-based methods. In this work, MDF determined from the method are well fit by three-Gaussian model, with peaks at [Fe/H]=-0.68, -1.38, and -1.90, associated with the thick disk, inner halo, and outer halo, respectively. The vertical metallicity gradient within 1<Z<5\, kpc is d [Fe/H]/ dZ≈ -0.19\, dex· kpc-1 around R=8.25\, kpc. But the mean radial gradient is almost negligible. The density profile of the thick disk is fitted with modified double exponential law decaying to a constant at far distance. The scale height and scale length thus estimated are H≈ 1.13\, kpc and L≈ 3.63\, kpc, which are in consistent with the results determined from star-counts method in previous studies. The halos are described with two-axial power-law ellipsoid and the axis ratios of both inner halo and outer halo, inferred from stellar number density in R-Z plane, are qih≈ 0.49 and qoh≈ 0.61, respectively. It also manifests that the outer halo is a more spherical than inner halo. Moreover, the halo power-law indices estimated are nih≈ 3.4 and noh≈ 3.1, indicating that the stellar number density of inner halo changes more steeper than that of outer halo.