Dark matter halo mass functions and density profiles from mass and energy cascade

Abstract

Without relying on a spherical or ellipsoidal collapse model, we analytically derive the halo mass function and cuspy halo density (inner slope of -4/3) based on the mass and energy cascade theory in dark matter flow. The hierarchical halo structure formation leads to halo or particle random walk with a position-dependent waiting time τg. The inverse mass cascade from small to large scales leads to the halo random walk in mass space with τg mh-λ, where mh is the halo mass and λ is a halo geometry parameter with predicted value of 2/3. The corresponding Fokker-Planck solution for halo random walk in mass space gives rise to the halo mass function with a power-law behavior on small scale and exponential decay on large scale. This can be further improved by considering two different λ for haloes below and above a critical mass scale mh*, i.e. a double-λ halo mass function. A double-γ density profile can be derived based on the particle random walk in 3D space with a position-dependent waiting time τg (r)-1 r-γ, where is the gravitational potential and r is the particle distance to halo center. Theory predicts γ=2/3 that leads to a cuspy density profile with an inner slope of -4/3, consistent with the predicted scaling laws from energy cascade. The Press-Schechter mass function and Einasto density profile are special cases of proposed models. The small scale permanence can be identified due to the scale-independent rates of mass and energy cascade, where density profiles of different halo masses and redshifts converge to the -4/3 scaling law (h r-4/3) on small scales. Theory predicts halo number density scales with mass as mh-1.9, while halo mass density scales as mh4/9. Results were compared against the Illustris simulations.