The Structure of the Milky Way's Hot Gas Halo

Abstract

The Milky Way's million degree gaseous halo contains a considerable amount of mass that, depending on its structural properties, can be a significant mass component. In order to analyze the structure of the Galactic halo, we use XMM-Newton Reflection Grating Spectrometer archival data and measure OVII K alpha absorption-line strengths toward 26 active galactic nuclei, LMC X-3, and two Galactic sources (4U 1820-30 and X1735-444). We assume a beta-model as the underlying gas density profile and find best-fit parameters of no = 0.46+0.74-0.35 cm-3, rc = 0.35+0.29-0.27 kpc, and beta = 0.71+0.13-0.14. These parameters result in halo masses ranging between M(18 kpc) = 7.5+22.0-4.6 x 108 Msun and M(200 kpc) = 3.8+6.0-0.5 x 1010 Msun assuming a gas metallicity of Z = 0.3 Zsun, which are consistent with current theoretical and observational work. The maximum baryon fraction from our halo model of fb = 0.07+0.03-0.01 is significantly smaller than the universal value of fb = 0.171, implying the mass contained in the Galactic halo accounts for 10% - 50% of the missing baryons in the Milky Way. We also discuss our model in the context of several Milky Way observables, including ram pressure stripping in dwarf spheroidal galaxies, the observed X-ray emission measure in the 0.5 - 2 keV band, the Milky Way's star formation rate, spatial and thermal properties of cooler gas (~105 K) and the observed Fermi bubbles toward the Galactic center. Although the metallicity of the halo gas is a large uncertainty in our analysis, we place a lower limit on the halo gas between the Sun and the Large Magellanic Cloud (LMC). We find that Z >~ 0.2 Zsun based on the pulsar dispersion measure toward the LMC.