Local Approximations to the Gravitational Collapse of Cold Matter

Abstract

We investigate three different local approximations for nonlinear gravitational instability in the framework of cosmological Lagrangian fluid dynamics of cold dust. They include the Zel'dovich approximation (ZA), the ``non-magnetic'' approximation of Bertschinger \& Jain (1994, NMA), and a new ``local tidal'' approximation (LTA). The LTA is exact for any perturbations whose gravitational and velocity equipotentials have the same constant shape with time, including spherical, cylindrical, and plane-parallel perturbations. We tested all three local approximations with the collapse of a homogeneous triaxial ellipsoid, for which an exact solution exists for an ellipsoid embedded in empty space and an excellent approximation is known in the cosmological context. We find that the LTA is significantly more accurate in general than the ZA and the NMA. Like the ZA, but unlike the NMA, the LTA generically leads to pancake collapse. For a randomly chosen mass element in an Einstein-de Sitter universe, assuming a Gaussian random field of initial density fluctuations, the LTA predicts that at least 78\% of initially underdense regions collapse owing to nonlinear effects of shear and tides.