期刊
ASTROPHYSICAL JOURNAL
卷 531, 期 1, 页码 1-16出版社
IOP PUBLISHING LTD
DOI: 10.1086/308436
关键词
cosmology : theory; galaxies : clusters : general; galaxies : formation
The clustering of galaxies relative to the underlying mass distribution declines with cosmic time for three reasons. First, nonlinear peaks become less rare events as the density field evolves. Second, the densest regions stop forming new galaxies because their gas becomes too hot to cool and collapse. Third, after galaxies form, they are subject to the same gravitational forces as the dark matter, and thus they tend to trace the dark matter distribution more closely with time; in this sense, they are gravitationally debiased. In order to illustrate these effects, we perform a large-scale hydrodynamic cosmological simulation of a A cold dark matter (Lambda CDM) model with Omega(0) = 0.37 and examine the statistics of delta*(r, z), the density held of recently formed galaxies at position r and redshift z. We find that the bias of recently formed galaxies b* equivalent to [delta*(2)](1/2)/[delta(2)](1/2), where delta is the mass overdensity, evolves from b* equivalent to similar to 4.5 at z = 3 to b* similar to 1 at z = 0, on 8 h(-1) Mpc comoving scales. The correlation coefficient r* equivalent to [delta delta*]/[delta(2)](1/2)[delta*(2)](1/2) evolves from r* similar to 0.9 at z = 3 to r* similar to 0.3 at z = 0. That is, as gas in the universe heats up and prevents star formation, the star-forming galaxies become poorer tracers of the mass density field. We show that the linear continuity equation is a good approximation for describing the gravitational debiasing, even on nonlinear scales. The most interesting observational consequence of the simulations is that the linear regression of the galaxy formation density held on the galaxy density held, b(*g)r(*g) = [delta*delta(g)]/[delta(g)(2)], evolves from about 0.9 at z = 1 to 0.35 at z = 0. Measuring this evolution, which should be possible using the Sloan Digital Sky Survey, would place constraints on models for galaxy formation. In addition, we evaluate the effects of the evolution of galaxy formation on estimates of Omega from cluster mass-to-light ratios, finding that while Omega(z) increases with z, the estimate Omega(est)(z) actually decreases. This effect is due to the combination of galaxy bias and the relative fading of cluster galaxies with respect to held galaxies. Finally, these effects provide a possible explanation for the Butcher-Oemler effect, the excess of blue galaxies in clusters at redshift z similar to 0.5.
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