The evolution of expanding, spherical-symmetric density perturbations is reviewed, mainly in the context of an Einstein-de Sitter universe, according to an exact theory and to a first-order and zeroth-order approximation. Then, following Ryden and Gunn (1987) and Ryden (1988), we model inhomogeneities as central peaks surrounded by secondary perturbations, and review and extend (according to a number of different approximations) the analytic expressions of the rms torque acting on a thin spherical mass shell, and of the angular momentum thus acquired. In particular, two extreme physical situations have been analysed: (i) the core of density perturbations, or more generally homogeneous density perturbations; and (ii) the envelope of density perturbations, or more generally density perturbations with halos reduced to the Hubble flow. Though in early times the torque grows in proportion to t2/3 and the angular momentum in proportion to t5/3, different approximations lead to different results even before density perturbations decouple strongly from the Hubble flow. An interpretation of the results is consistent with a suggestion by Peebles (1969), that physical processes leading to the torques under consideration are switched off during the above-mentioned strong decoupling. After this epoch, a given approximation might have mathematical features which are not in contradiction with the physical meaning of the problem, but no physical meaning in itself; from a physical point of view, any approximation should be smoothed, or truncated. Additional support to this conclusion comes from a qualitative estimate of the angular momentum, and then of the spin parameter, related to the whole density perturbations under a number of simplifying assumptions; accordingly, the acquisition of angular momentum appears to end at late rather than at early stages of strong decouling. The related values of the spin parameter are λ greater-than or equivalent to 0.02, which is consistent with λ greater-than or equivalent to 0.05 found by both Barnes and Efstathiou (1987) using numerical computations based on N-body simulations, and Heavens and Peacock (1988) using analytical approximations. The results are also in agreement with current estimations of the Milky Way angular momentum.

Acquisition of angular momentum by tidal torques in expanding, spherical-symmetric density perturbations - an analysis of different approximations

CAIMMI, ROBERTO
1989

Abstract

The evolution of expanding, spherical-symmetric density perturbations is reviewed, mainly in the context of an Einstein-de Sitter universe, according to an exact theory and to a first-order and zeroth-order approximation. Then, following Ryden and Gunn (1987) and Ryden (1988), we model inhomogeneities as central peaks surrounded by secondary perturbations, and review and extend (according to a number of different approximations) the analytic expressions of the rms torque acting on a thin spherical mass shell, and of the angular momentum thus acquired. In particular, two extreme physical situations have been analysed: (i) the core of density perturbations, or more generally homogeneous density perturbations; and (ii) the envelope of density perturbations, or more generally density perturbations with halos reduced to the Hubble flow. Though in early times the torque grows in proportion to t2/3 and the angular momentum in proportion to t5/3, different approximations lead to different results even before density perturbations decouple strongly from the Hubble flow. An interpretation of the results is consistent with a suggestion by Peebles (1969), that physical processes leading to the torques under consideration are switched off during the above-mentioned strong decoupling. After this epoch, a given approximation might have mathematical features which are not in contradiction with the physical meaning of the problem, but no physical meaning in itself; from a physical point of view, any approximation should be smoothed, or truncated. Additional support to this conclusion comes from a qualitative estimate of the angular momentum, and then of the spin parameter, related to the whole density perturbations under a number of simplifying assumptions; accordingly, the acquisition of angular momentum appears to end at late rather than at early stages of strong decouling. The related values of the spin parameter are λ greater-than or equivalent to 0.02, which is consistent with λ greater-than or equivalent to 0.05 found by both Barnes and Efstathiou (1987) using numerical computations based on N-body simulations, and Heavens and Peacock (1988) using analytical approximations. The results are also in agreement with current estimations of the Milky Way angular momentum.
1989
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11577/2505328
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