Low-mass stars dominate the hot (0.7 keV) Galactic X-ray emission

TL;DR

This study reveals that low-mass stars significantly contribute to the 0.7 keV X-ray emission in the Milky Way, challenging previous assumptions about the hot circumgalactic medium's composition.

Contribution

It demonstrates a strong correlation between 0.7 keV X-ray emission and stellar mass distribution, highlighting the dominance of unresolved low-mass stars in this emission.

Findings

Low-mass stars account for a large fraction of the 0.7 keV emission.

The X-ray luminosity per unit stellar mass is comparable to local low-mass stars.

The hot super-virial component's density is constrained to be very low at 10 kpc.

Abstract

The circumgalactic medium (CGM) of the Milky Way is composed of a tenuous atmosphere filled with multi-phase plasma, including a warm-hot virialised component. Recent studies suggest a much hotter (~0.7 keV) super-virial component detected in both absorption and emission. We want to shed light on the nature of this putative super-virial component. We analysed the X-ray background as observed by SRG/eROSITA over the entire western Galactic hemisphere. We show that low-mass stars provide a large fraction of the 0.7 keV emission. Indeed, a tight correlation is found between the surface brightness of the 0.7 keV emission and the mass distribution of the Milky Way across a large portion of the western Galactic hemisphere. The correlation coefficient implies an X-ray luminosity per unit of stellar mass comparable to that of the average low-mass stars within 10 pc of the Sun, suggesting that unresolved M dwarfs and F, G, and K type stars dominate the 0.7 keV emission. This emission is asymmetric with respect to the Galactic plane, influenced by the asymmetric distribution of nearby star-forming regions, and broadly consistent with the known offset of the Sun above the Galactic midplane. The remaining signal might be produced by the cumulative emission of stars of different types or ages, in addition to other sources (e.g. hot interstellar medium, Galactic corona, etc.). Assuming that the putative residual hot super-virial atmosphere is homogeneous and has a spherical beta profile with slope $\beta=0.4$, we constrain its density at 10 kpc to be $n_e<4\times10^{-4}$~cm$^{-3}$. Our findings may help refine models of the circumgalactic medium around external galaxies, advancing our understanding of hot baryon flows and galaxy evolution.