The hot circumgalactic medium in stacked X-rays: observations vs simulations

Abstract: Current cosmological simulations rely on active galactic nuclei (AGN) feedback to quench star formation and match observed stellar mass distributions, but models for AGN feedback are poorly constrained. The circumgalactic medium (CGM) provides a helpful laboratory to study this process, as its metallicity, temperature, and density distributions are directly impacted by AGN. Recent observations from the eROSITA instrument provide constraints on these distributions through measurements of extended soft X-ray emission. Here, we generate synthetic eROSITA observations from the EAGLE and SIMBA cosmological simulations, comparing them against observations of galaxies stacked by stellar mass, halo mass, and star-formation rate. SIMBA outperforms EAGLE in matching observed surface brightness profiles in general, but neither simulation consistently agrees with observations across the full range of galaxy properties we studied. We find that variations in CGM X-ray emission between simulations are driven by density differences at $R \lesssim 0.2 R_{200c} $, and temperature and metallicity changes at larger radii. We directly model predicted contributions from X-ray binaries (XRBs), finding that the hot plasma contributes $\approx$ 20 times more to the CGM X-ray luminosity than XRBs, except at $M_*<10^{11} M_\odot$, where the contamination from XRBs becomes more significant.