Probing the physical properties of the IGM using SRG/eROSITA spectra from blazars

Abstract

Most baryonic matter resides in the intergalactic medium (IGM), a diffuse gas primarily composed of ionized hydrogen and helium, filling the space between galaxies. Observations of such an environment are crucial to better understanding the physical processes involved in such an environment. We present an analysis of the IGM absorption using blazar spectra from the first eROSITA all-sky survey (eRASS1) performed onboard of the Spectrum-Roentgen-Gamma mission (SRG) and XMM-Newton X-ray observations. First, we fitted the continuum spectra using a log-parabolic spectrum model and fixed the Galactic absorption. Then, we included a collisional ionization equilibrium model, namely IONeq, to account for the IGM absorption. The column density N( H) and metallicity (Z) were set as free parameters. At the same time, the redshift of the absorber was fixed to half the blazar redshift as an approximation of the full line-of-sight absorber. We measured IGM-N( H) for 147 sources for SRG and 10 sources for XMM-Newton. We found a clear trend between IGM-N( H) and the blazar redshifts which scales as (1+z)1.63 0.12. The mean hydrogen density at z=0 is n0=(2.75 0.63)× 10-7 cm-3. The mean temperature over the redshift range is (T/K)=5.6 0.6 while the mean metallicity is Z=0.16 0.09. We found no acceptable fit using a power-law model for either temperatures or metallicities as a function of the redshift. These results indicate that the IGM contributes substantially to the total absorption seen in the blazar spectra.