Naoki Seto
Published 2000-02-18Version 1
Cosmological linear perturbation theory predicts that the peculiar velocity $V(x)$ and the matter overdensity $\delta(x)$ at a same point $x$ are statistically independent quantities, as log as the initial density fluctuations are random Gaussian distributed. However nonlinear gravitational effects might change the situation. Using framework of second-order perturbation theory and the Edgeworth expansion method, we study local density dependence of bulk velocity dispersion that is coarse-grained at a weakly nonlinear scale. For a typical CDM model, the first nonlinear correction of this constrained bulk velocity dispersion amounts to $\sim 0.3\delta$ (Gaussian smoothing) at a weakly nonlinear scale with a very weak dependence on cosmological parameters. We also compare our analytical prediction with published numerical results given at nonlinear regimes.
Comments: 16 pages including 2 figures, ApJ 537 in press (July 1)
Journal: Astrophys.J. 537 (2000) 21
Non-Linear Approximations to Gravitational Instability: A Comparison in Second-Order Perturbation Theory
Statistics of smoothed cosmic fields in perturbation theory I: Formulation and useful formulas in second-order perturbation theory
Weakly Non-Linear Gaussian Fluctuations and the Edgeworth Expansion
