Abstract
We use numerical simulations of structure formation in a cold dark matter cosmology to compare the angular momentum distributions of dark matter and nonradiative gas in a large sample of halos. We show that the two components have identical spin parameter distributions and that their angular momentum distributions within individual halos are very similar, all in excellent agreement with standard assumptions. Despite these similarities, however, we find that the angular momentum vectors of the gas and dark matter are poorly aligned, with a median misalignment angle of � 30 � , which might have important implications for spin correlation statistics used in weak lensing studies. We present distributions for the component of the angular momentum that is aligned with the total angular momentum of each halo and find that for between 5% and 50% of the mass, this component is negative. This disagrees with the generally adopted ‘‘ universal ’’ angular momentum distribution, for which the mass fraction with negative specific angular momentum is zero. We discuss the implications of our results for the formation of disk galaxies. Since galactic disks generally do not contain counterrotating stars or gas, disk formation cannot occur under detailed conservation of specific angular momentum. We suggest that the material with negative specific angular momentum combines with positive angular momentum material to build a bulge component, and we show that in such a scenario the remaining material can form a disk with a density distribution that is very close to exponential. Subject headings: dark matter — galaxies: formation — galaxies: halos — galaxies: structure — methods: n-body simulations
Highlights
Understanding the structure and formation of disk galaxies is intimately linked to understanding the origin of its angular momentum
We suggest that the material with negative specific angular momentum combines with positive angular momentum material to build a bulge component, and show that in such a scenario the remaining material can form a disk with a density distribution that is very close to exponential
For the dark matter we find λDM = 0.040 and σλDM = 0.56, while for the gas λgas = 0.039 and σλgas = 0.57
Summary
Understanding the structure and formation of disk galaxies is intimately linked to understanding the origin of its angular momentum. In hierarchical structure formation scenarios the luminous parts of galaxies form from gas that is cooling and condensing within dark matter (DM) halos and these merge to build larger and larger objects (White & Rees 1978). Within this picture, the current paradigm for disk formation contains three important ingredients: (i) the angular momentum originates from cosmological torques (Hoyle 1953), (ii) the gas and dark matter within virialized systems have initial angular momentum distributions that are identical (Fall & Efstathiou 1980), and (iii) the gas conserves its specific angular momentum when cooling (Mestel 1963). The specific angular momentum of halos is typically parameterized by the dimensionless spin parameter λ
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