Astronomy and Astrophysics – Astronomy
Scientific paper
Nov 1993
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=1993apj...417..404c&link_type=abstract
Astrophysical Journal v.417, p.404
Astronomy and Astrophysics
Astronomy
96
Cosmology: Theory, Galaxies: Intergalactic Medium, Cosmology: Diffuse Radiation, Galaxies: Formation
Scientific paper
We have supplemented our code, which computes the evolution of the physical state of a representative piece of the universe to include, not only the dynamics of dark matter (with a standard PM code), and the hydrodynamics of the gaseous component (including detailed collisional and radiative processes), but also galaxy formation on a heuristic but plausible basis. If, within a cell the gas is Jeans unstable, collapsing, and cooling rapidly, it is transformed to galaxy subunits, which are then followed with a collisionless code. These particles emit UV radiation and supernova blasts with energy efficiencies (in units of mc2) equal to (ɛUV, ɛSN) = (10-4 , 10-4.5). This energy input significantly alters some aspects of the simulation; the primary consequences are to heat and ionize the gas at a much earlier epoch than if stellar feedback were ignored. We study two representative boxes with sizes L = (80, 8)h-1 Mpc, in both cases utilizing a 2003 mesh containing 2003 dark matter particles and having nominal resolutions of (400, 40)h-1 kpc, respectively, with true resolution approximately 2.5 times worse. We adopt the standard CDM perturbation spectrum with an amplitude of σ8 ≡ (δM/M)rms,8 = 0.77, a compromise between the COBE normalization σ8 = 1.05 and that indicated by the small-scale velocity dispersion (perhaps σ8 = 0.45).
We find that by the time that 0.2% of the baryons have been transformed to stars at redshift 8.6, reionization is ½ complete, and observed Gunn-Peterson limits to a redshift of Ζ = 5 are satisfied. Very hot (107 - 108 K) gas is produced by shocks in the clusters, lower temperature (106 K) gas from supernova-fed superwinds is in lower density filaments and sheets and photo-heated gas (104-105 K) fills the voids. The mass fractions in these components at redshift zero being roughly (29%, 40%, 31%) correspond to gas in the temperature ranges (<105.5, 105.5-106.5, >106.5) K.
In rich clusters the galaxy and dark matter densities are more concentrated than the gas density in agreement with gravitational lens observations. We can combine the observed and computed baryon to total mass ratios with Ωb from light element nucleosynthesis, and we conclude that we live in an open universe with Ωtot = (0.11, 0.24) for h = (1.0, 0.5). While the correspondence between the thermodynamic properties of gas and radiation fields of this CDM model and the real world can be taken as support for the former, it is likely that many of the attributes of this simulation are generic, the result of a detailed physical treatment of atomic processes, and will be found as well in rival cosmological models.
Cen Renyue
Ostriker Jeremiah P.
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