The soft X-ray background with Suzaku: I. Milky Way halo

TL;DR

This study analyzes Suzaku X-ray observations to characterize the Milky Way halo's hot gas, revealing a nearly uniform temperature and emission measure, with evidence for a disk-like component and implications for the galaxy's mass and halo structure.

Contribution

It introduces a refined model of the Milky Way halo incorporating both spherical and disk-like components, accounting for SWCX contamination, and estimates the halo's gas mass and hydrostatic equilibrium status.

Findings

The halo's temperature is approximately 0.22 keV.

The emission measure is about 2×10^{-3} cm^{-6} pc.

The halo likely contains a few times 10^{10} solar masses of gas.

Abstract

We present measurements of the soft X-ray background emission for 130 Suzaku observations at $75^\circ<l < 285^\circ$ and $|b|>15^\circ$ obtained from 2005 to 2015, covering nearly one solar cycle. In addition to the standard soft X-ray background model consisting of the local hot bubble and the Milky Way Halo (MWH), we include a hot collisional-ionization-equilibrium component with a temperature of $\sim 0.8$ keV to reproduce spectra of a significant fraction of the lines of sight. Then, the scatter in the relation between the emission measure vs. temperature of the MWH component is reduced. Here, we exclude time ranges with high count rates to minimize the effect of the solar wind charge exchange (SWCX). However, the spectra of almost the same lines of sight are inconsistent. The heliospheric SWCX emissions likely contaminate and gives a bias in measurements of temperature and the emission measure of the MWH. Excluding the data around the solar maximum and using the data taken before the end of 2009, at $|b|>35^\circ$ and $105^\circ<l<255^\circ$, the temperature (0.22 keV) and emission measure ($2\times 10^{-3}~\rm{cm^{-6}pc}$) of the MWH are fairly uniform. The increase of the emission measure toward the lower Galactic latitude at $|b|<35^\circ$ indicates a presence of a disk-like morphology component. A composite model which consists of disk-like and spherical-morphology components also reproduces the observed emission measure distribution of MWH. In this case, the hydrostatic mass at a few tens of kpc from the Galactic center agrees with the gravitational mass of the Milky Way. The plasma with the virial temperature likely fills the Milky Way halo in nearly hydrostatic equilibrium. Assuming the gas metallicity of 0.3 solar, the upper limit of the gas mass of the spherical component out to 250 kpc, or the virial radius, is $\sim$ a few $\times 10^{10}~ M_\odot$.