Three- and two-point spatial correlations of IGM at z 2: Cloud based analysis using simulations

Abstract

Lyα forest absorption spectra decomposed into multiple Voigt profile components (clouds) allow us to study clustering of intergalactic medium (IGM) as a function of HI column density (N HI). Here, we explore the transverse three-point correlation (ζ) of these Lyα clouds using mock triplet spectra obtained from hydrodynamical simulations at z 2 on scales of 1-5 h-1cMpc. We find ζ to depend strongly on N HI and scale and weakly on angle (θ) of the triplet configuration. We show that the "hierarchical ansatz" is applicable for scales ~ 3h-1cMpc, and obtain a median reduced three-point correlation (Q) in the range 0.2-0.7. We show, ζ is influenced strongly by the thermal and ionization state of the gas. As found in the case of galaxies, the influence of physical parameters on Q is weaker compared to that of ζ. We show difference in ζ and Q between different simulations are minimized if we use appropriate N HI cut-offs corresponding to a given baryon over-density () using the measured N HI~vs~ relationship obtained from individual simulations. Additionally, we see the effect of pressure broadening on ζ in a model with artificially boosted heating rates. However, for models with realistic thermal and ionization histories the effect of pressure broadening on ζ is weak and sub-dominant compared to other local effects. We find strong redshift evolution shown by ζ, mainly originating from the redshift evolution of thermal and ionization state of the IGM. We discuss the observational requirements for the detection of three-point correlation, specifically, in small intervals of configuration parameters and redshift.