Astronomy and Astrophysics – Astrophysics
Scientific paper
1999-03-28
Astronomy and Astrophysics
Astrophysics
27 pages, including 5 figures. MNRAS Latex preprint format. Submitted to MNRAS (March 1999)
Scientific paper
We calculate the maximum fraction of matter which is able to condense out of the expanding background universe, for any universe which will expand forever. We use a simple spherical model for the growth of density fluctuations in the universe. This model includes open, matter-dominated universe and universes in which there is an uniform background component (e.g. the cosmological constant or "quintessence"). In these background universes, Omega eventually drops significantly below unity. When this happens, gravitational instability is suppressed and, with it, so is the growth of the collapsed fraction. We identify a limitation of the Press-Schechter (PS) approximation. In this approximation, the mass function determined from the predicted collapse of overdense regions is multiplied by a correction factor of 2, assuming that each bound fluctuation will accrete an equal share of mass from nearby underdense regions. Our model determines the actual value of the correction factor. We show that, while the factor of 2 adopted by the PS approximation is correct for an Einstein-de Sitter universe, it is not correct when the freeze-out of fluctuation growth inherent in the more general class of background universes described above occurs. When freeze-out occurs, the correction factor reduces to unity and the PS approximation must overestimate the collapsed fraction. We apply our model to open CDM and flat Lambda-CDM models. For H0=70 and Omega0=0.3, these models yield asymptotic collapsed fractions of 0.0361 and 0.0562, respectively, on the galaxy cluster mass-scale, only 55% of the values determined by the PS approximation. These results have implications for the use of the latter approximation to compare the observed space density of X-ray clusters today with that predicted by cosmological models.
Martel Hugo
Shapiro Paul R.
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