Virial Scaling of Massive Dark Matter Halos: Why Clusters Prefer a High Normalization Cosmology
Abstract
We present a precise estimate of the bulk virial scaling relation of halos formed via hierarchical clustering in an ensemble of simulated cold dark matter cosmologies. The result is insensitive to cosmological parameters; the presence of a trace, dissipationless gas component; and numerical resolution down to a limit of ~1000 particles. The dark matter velocity dispersion scales with total mass as log [σDM(M,z)] = = log(1082.9 +/- 4.0 km s-1) + (0.3361 +/- 0.0026)log[h(z)M200/1015 M⊙], with h(z) being the dimensionless Hubble parameter. At fixed mass, the velocity dispersion likelihood is nearly lognormal, with scatter σln σ = 0.0426 +/- 0.015, except for a tail with higher dispersions containing 10% of the population that are merger transients. We combine this relation with the halo mass function in ΛCDM models and show that a low normalization condition, S8 = σ8(Ωm/0.3)0.35 = 0.69, favored by recent WMAP and SDSS analysis requires that galaxy and gas-specific energies in rich clusters be 50% larger than that of the underlying dark matter. Such large energetic biases are in conflict with the current generation of direct simulations of cluster formation. A higher normalization, S8 = 0.80, alleviates this tension and implies that the hot gas fraction within r500 is ( 0.71+/- 0.09) h-3/ 270 Ω b/ Ω m, a value consistent with recent Sunyaev-Zel'dovich observations.
- Publication:
-
The Astrophysical Journal
- Pub Date:
- January 2008
- DOI:
- 10.1086/521616
- arXiv:
- arXiv:astro-ph/0702241
- Bibcode:
- 2008ApJ...672..122E
- Keywords:
-
- cosmology: miscellaneous;
- cosmology: theory;
- dark matter;
- galaxies: clusters: general;
- gravitation;
- intergalactic medium;
- Astrophysics
- E-Print:
- 18 pages, 13 figures (Fig. 10 revised). Revised version accepted to ApJ incorporating changes requested by referee, including a bootstrap approach to errors in the overall fit parameters and a caveat about the dissipationless treatment of baryons in the current set of models. ApJ, in press