Gravitational instability of cold matter

Abstract

view Abstract Citations (95) References (47) Co-Reads Similar Papers Volume Content Graphics Metrics Export Citation NASA/ADS Gravitational Instability of Cold Matter Bertschinger, Edmund ; Jain, Bhuvnesh Abstract We solve the nonlinear evolution of pressureless, irrotational density fluctuations in a perturbed Robertson-Walker spacetime using a new Lagrangian method based on the velocity gradient and gravity gradient tensors. Borrowing results from general relativity, we obtain a set of Newtonian ordinary differential equations for these quantities following a given mass element. Using these Lagrangian fluid equations we prove the following results: (1) The spherical tophat perturbation, having zero shear, is the slowest configuration to collapse for a given initial density and growth rate. (2) Initial density maxima are not generally the sites where collapse first occurs. (3) Initially underdense regions may undergo collapse if the shear is not too small. If the magnetic part of the Weyl tensor vanishes, the nonlinear evolution is described purely locally by our equations; this condition holds for spherical, cylindrical, and planar perturbations and may be a good approximation in other circumstances. Assuming the vanishing of the magnetic part of the Weyl tensor, we compute the exact nonlinear gravitational evolution of cold matter. We find that 56\% of initially underdense regions collapse in an Einstein-de Sitter universe for a homogeneous and isotropic random field. We also show that, given this assumption, the final stage of collapse is generically two-dimensional, leading to strongly prolate filaments rather than Zel'dovich pancakes. While this result may explain the prevalence of filamentary collapses in N-body simulations, it is not true in general, suggesting that the magnetic part of the Weyl tensor need not vanish in the Newtonian limit. Publication: The Astrophysical Journal Pub Date: August 1994 DOI: 10.1086/174501 arXiv: arXiv:astro-ph/9307033 Bibcode: 1994ApJ...431..486B Keywords: Cold Plasmas; Dark Matter; Galactic Evolution; Gravitational Collapse; Gravitational Fields; Cosmology; Differential Equations; Gravity Anomalies; Perturbation Theory; Red Shift; Velocity Distribution; Astrophysics; COSMOLOGY: THEORY; COSMOLOGY: DARK MATTER; INSTABILITIES; COSMOLOGY: LARGE-SCALE STRUCTURE OF UNIVERSE; Astrophysics; General Relativity and Quantum Cosmology E-Print: 23 pages, AAS LaTeX 3.0, postscript with figures available by anonymous ftp to arcturus.mit.edu, revised version of MIT CSR-93-14 full text sources arXiv | ADS |