Halo mass functions from maximum entropy distributions in collisionless dark matter flow
Abstract
The halo-mediated inverse mass cascade is a key feature of the intermediate statistically steady state for self-gravitating collisionless dark matter flow (SG-CFD). A broad spectrum of halos and halo groups are necessary to form from inverse mass cascade for long-range interaction system to maximize its entropy. The limiting velocity ( X), speed ( Z), and energy ( E) distributions of collisionless particles can be obtained analytically from a maximum entropy principle. Halo mass function, the distribution of total mass in halos, is a fundamental quantity for structure formation and evolution. Instead of basing mass functions on simplified spherical/elliptical collapse models, it is possible to reformulate mass function as an intrinsic distribution to maximize system entropy during the everlasting statistically steady state. Starting from halo-based description of non-equilibrium dark matter flow, distributions of particle virial dispersion ( H), square of particle velocity ( P), and number of halos ( J) are proposed. Their statistical properties and connections with velocity distribution ( X) are well studied and established. With H being essentially the halo mass function, two limiting cases of H distribution are analyzed for large halos ( H∞) and small halos ( Hs), respectively. For large halos, H∞ is shown to also be a maximum entropy distribution. For small halos, Hs approximates the P distribution and recovers the Press-Schechter mass function. The full solution of H distribution is determined by the velocity distribution ( X) that maximizes system entropy and the exact model of halo velocity dispersion.
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