Journal
MONTHLY NOTICES OF THE ROYAL ASTRONOMICAL SOCIETY
Volume 439, Issue 3, Pages 2505-2514Publisher
OXFORD UNIV PRESS
DOI: 10.1093/mnras/stu107
Keywords
galaxies: clusters: general; galaxies: groups: general; cosmological parameters; cosmology: observations; dark matter; large-scale structure of Universe
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Funding
- NSF graduate research fellowship
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How is mass distributed in the Universe? How does it compare with the distribution of light and stars? We address these questions by examining the distribution of mass, determined from weak lensing observations, and starlight, around > 10(5) Sloan Digital Sky Survey MaxBCG groups and clusters as a function of environment and scale, from deep inside clusters to large cosmic scales of 22 h(-1) Mpc. The observed cumulative mass-to-light profile, M/L (< r), rises on small scales, reflecting the increasing M/L of the central bright galaxy of the cluster, then flattens to a nearly constant ratio on scales above similar to 300 h(-1) kpc, where light follows mass on all scales and in all environments. A trend of slightly decreasing M/L (r) with scale is shown to be consistent with the varying stellar population following the morphology-density relation. This suggests that stars trace mass remarkably well even though they represent only a few per cent of the total mass. We determine the stellar mass fraction and find it to be nearly constant on all scales above similar to 300 h(-1) kpc, with M-*/M-tot similar or equal to 0.01 +/- 0.004. We further suggest that most of the dark matter in the Universe is located in the large haloes of individual galaxies (similar to 300 kpc for L* galaxies); we show that the entire M/L (r) profile - from groups and clusters to large-scale structure - can be accounted for by the aggregate masses of the individual galaxies (whose haloes may be stripped off but still remain in the clusters), plus gas. We use the observed M/L ratio on large scales to determine the mass density of the Universe: Omega(m) = 0.24 +/- 0.02b(M/L)(2) = 0.26 +/- 0.2.
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