Influence of baryons on spatial distribution of matter: higher order correlation functions

Abstract

Baryonic physical processes could leave non-negligible imprint on cosmic matter distribution pattern. Series of high precision simulation data sets with identical initial condition are employed for count-in-cell (CIC) analysis, including one N-body dark matter run, one with adiabatic gas only and one with dissipative processes. Variances and higher order correlation functions of dark matter and gas are estimated. It is found that baryon physical processes mainly affected dark matter distribution at scales less than 1h-1Mpc. In comparison with the pure dark matter run, adiabatic process alone strengthens variance of dark matter by 10% at scale 0.1h-1Mpc, while Sns of dark matter deviate from pure dark matter case only mildly at a few percentages. Dissipative gas run does not differ much to the adiabatic run in dark matter variance, but renders significantly different Sn parameters of dark matter, bringing about more than 10% enhancement to S3 at 0.1h-1Mpc and z=0. Distribution patterns of gas in two hydrodynamical simulations are prominently different. Variance of gas at z=0 decreases by 30% in adiabatic simulation while by 60% in non-adiabatic simulation at 0.1h-1Mpc, the attenuation is weaker at larger scales but still obvious at 10h-1Mpc. Sn parameters of gas are biased upward at scales < 4h-1Mpc, dissipative processes give 84% promotion at z=0 to S3 at 0.1h-1Mpc against the moderate 7% in adiabatic simulation. The clustering segregation we observed between gas and dark matter could have intricate implication on modeling galaxy distribution and relevant cosmological application demanding fine details of matter distribution in strongly nonlinear regime.