On the Shoulders of Giants: Properties of the Stellar Halo and the Milky Way Mass Distribution

Abstract

Halo stars orbit within the potential of the Milky Way and hence their kinematics can be used to understand the underlying mass distribution. However, the inferred mass distribution depends sensitively upon assumptions made on the density and the velocity anisotropy profiles of the tracers. Also, there is a degeneracy between the parameters of the halo and that of the disk or bulge. Here, we decompose the Galaxy into bulge, disk and dark matter halo and then model the kinematic data of the halo BHB and K-giants from the SEGUE. Additionally, we use the gas terminal velocity curve and the Sgr A* proper motion. With R = 8.5kpc, our study reveals that the density of the stellar halo has a break at 17.2+1.1-1.0 kpc, and an exponential cut-off in the outer parts starting at 97.7+15.6-15.8kpc. Also, we find the velocity anisotropy is radially biased with βs= 0.40.2 in the outer halo. We measure halo virial mass Mvir = 0.80+0.31-0.16 × 1012 M, concentration c=21.1+14.8-8.3, disk mass of 0.95+0.24-0.30×1011 M, disk scale length of 4.9+0.4-0.4 kpc and bulge mass of 0.91+0.31-0.38 × 1010 M. The mass of halo is found to be small and this has important consequences. The giant stars reveal that the outermost halo stars have low velocity dispersion interestingly suggesting a truncation of the stellar halo density rather than a small overall mass of the Galaxy. Our estimates of local escape velocity v esc = 550.9+32.4-22.1 kms-1 and dark matter density DM = 0.0088+0.0024-0.0018 M pc-3 (0.35+0.08-0.07 GeV cm-3) are in good agreement with recent estimates. Some of the above estimates are depended on the adopted value of R and of outer power-law index of the tracer number density.