2019-06-18T13:03:37Z
https://digital.csic.es/dspace-oai/request
oai:digital.csic.es:10261/140515
2018-06-25T07:57:58Z
com_10261_37
com_10261_4
col_10261_290
Arnalte-Mur, P.
Vielva, P.
Martínez, Vicente J.
Sanz, J. L.
Saar, Enn
Paredes, Silvestre
2016-11-21T13:15:39Z
2016-11-21T13:15:39Z
2016
Journal of Cosmology and Astroparticle Physics 03: 005 (2016)
http://hdl.handle.net/10261/140515
10.1088/1475-7516/2016/03/005
We present a full description of the N-probability density function of the galaxy number density fluctuations. This N-pdf is given in terms, on the one hand, of the cold dark matter correlations and, on the other hand, of the galaxy bias parameter. The method relies on the assumption commonly adopted that the dark matter density fluctuations follow a local non-linear transformation of the initial energy density perturbations. The N-pdf of the galaxy number density fluctuations allows for an optimal estimation of the bias parameter (e.g., via maximum-likelihood estimation, or Bayesian inference if there exists any a priori information on the bias parameter), and of those parameters defining the dark matter correlations, in particular its amplitude (σ). It also provides the proper framework to perform model selection between two competitive hypotheses. The parameters estimation capabilities of the N-pdf are proved by SDSS-like simulations (both, ideal log-normal simulations and mocks obtained from Las Damas simulations), showing that our estimator is unbiased. We apply our formalism to the 7th release of the SDSS main sample (for a volume-limited subset with absolute magnitudes M -20). We obtain = 1.193 ± 0.074 and σ = 0.862 ± 0.080, for galaxy number density fluctuations in cells of the size of 30hMpc. Different model selection criteria show that galaxy biasing is clearly favoured.
eng
closedAccess
Joint constraints on galaxy bias and σ8 through the N-pdf of the galaxy number density
Artículo