Evolution of skewness and kurtosis of cosmic density fields

Abstract

Methods. We perform numerical simulations of the evolution of the cosmic web for the conventional LCDM model. The simulations cover a wide range of box sizes L = 256 - 4000 Mpc/h, mass and force resolutions and epochs from very early moments z = 30 to the present moment z = 0. We calculate density fields with various smoothing lengths to find the dependence of the density field on smoothing scale. We calculate PDF and its moments - variance, skewness and kurtosis. Results. We focus on the third (skewness S) and fourth (kurtosis K) moments of the distribution functions: their dependence on the smoothing scale, the amplitude of fluctuations and the redshift. During the evolution the reduced skewness S3= S/σ and reduced kurtosis S4=K/σ2 present a complex behaviour: at a fixed redshift curves of S3(σ) and S4(σ) steeply increase with σ at σ 1 and then flatten out and become constant at σ2. If we fix the smoothing scale Rt, then after reaching the maximum at σ≈ 2, the curves at large σ start to gradually decline. We provide accurate fits for the evolution of S3,4(σ,z). Skewness and kurtosis approach at early epochs constant levels, depending on smoothing length: S3(σ) ≈ 3 and S4(σ) ≈ 15. Conclusions. Most of statistics of dark matter clustering (e.g., halo mass function or concentration-mass relation) are nearly universal: they mostly depend on the σ with the relatively modest correction to explicit dependence on the redshift. We find just the opposite for skewness and kurtosis: the dependence of moments on evolutionary epoch z and smoothing length Rt is very different, together they determine the evolution of S3,4(σ) uniquely. The evolution of S3 and S4 cannot be described by current theoretical approximations.