Probing the cosmic baryon distribution and the impact of AGN feedback with FRBs in CROCODILE simulation

Abstract: We investigate the Missing Baryon problem using Fast Radio Bursts (FRBs) to trace cosmic baryons. We use the CROCODILE simulations with the GADGET3/4-OSAKA SPH code, incorporating star formation, supernova (SN), and active galactic nuclei (AGN) feedback. Light cones generated from large-scale structure simulations allow us to compute gas density profiles and dispersion measures (DMs) measurable by FRBs. Our results show that AGN feedback reduces central gas densities in halos, reshaping the boundary between the circumgalactic medium (CGM) and intergalactic medium (IGM). Zoom-in simulations further reveal that AGN feedback significantly modulates foreground halo DM contributions along different sightlines. By analyzing the DM--redshift (DM--z) relation and comparing it to the Macquart relation, we constrain the diffuse baryon mass fraction at z = 1 to fdiff = 0.865 (+0.101, -0.165) (fiducial) and fdiff = 0.856 (+0.101, -0.162) (NoBH), including IGM (fIGM) and halo (fHalos) contributions. We also quantify the redshift evolution of fdiff and fIGM, providing the fitting results. Our study provides a framework for understanding baryon distribution across cosmic structures, FRB host galaxies, and the role of AGN in shaping foreground DM contributions.