1 research outputs found
Halo mass function in scale invariant models
Sheth-Tormen mass function has been widely used to quantify the abundance of
dark matter halos. It is a significant improvement over the Press-Schechter
mass function as it uses ellipsoidal collapse in place of spherical collapse.
Both of these mass functions can be written in a form that is universal, i.e.,
independent of cosmology and power spectrum when scaled in suitable variables.
However, cosmological simulations have shown that this universality is
approximate. In this paper, we investigate the power spectrum dependence of
halo mass function through a suite of dark-matter-only N-body simulations of
seven power-law models in an Einstein-de Sitter cosmology. This choice of
cosmology and a power-law power spectrum ensures the self-similar evolution of
dark matter distribution, allowing us to isolate the power spectrum dependence
of mass function. We find that the mass function shows a clear
non-universality. We present fits for the parameters of the Sheth-Tormen mass
function for a range of power-law power-spectrum indices. We find a mild
evolution in the overall shape of the mass function with the epoch. Finally, we
extend our result to LCDM cosmology. We show that the Sheth-Tormen mass
function with parameter values derived from a matched power-law EdS cosmology
provides a better fit to the LCDM mass function than the standard Sheth-Tormen
mass function. Our results indicate that an improved analytical theory is
required to provide better fits to the mass function.Comment: 11 pages, 10 figures. This is a much expanded and upgraded version of
0908.2702. Submitted to MNRA