Tree structure of the percolating Universe
arXiv:astro-ph/0011293 · doi:10.1103/PhysRevLett.85.5515
Abstract
We present a numerical study of topological descriptors of initially Gaussian and scale-free density perturbations evolving via gravitational instability in an expanding universe. We carefully evaluate and avoid numerical contamination in making accurate measurements on simulated fields on a grid in a finite box. Independent of extent of non linearity, the measured Euler number of the excursion set at the percolation threshold, $δ_c$, is positive and nearly equal to the number of isolated components, suggesting that these structures are trees. Our study of critical point counts reconciles the clumpy appearance of the density field at $δ_c$ with measured filamentary local curvature. In the Gaussian limit, we measure $|δ_c|> Ï$ in contrast to widely held belief that $|δ_c| \sim Ï$, where $Ï^2$ is the variance of the density field.
4 pages, 2 figures, Accepted for publication in Phys. Rev. Lett