We present an analysis of the cross-correlation between the CMB and the large-scale structure (LSS) of the Universe in Unified Dark Matter (UDM) scalar field cosmologies. We work out the predicted cross-correlation function in UDM models, which depends on the speed of sound of the unified component, and compare it with observations from six galaxy catalogues (NVSS, HEAO, 2MASS, and SDSS main galaxies, luminous red galaxies, and quasars). We sample the value of the speed of sound and perform a likelihood analysis, finding that the UDM model is as likely as the LambdaCDM, and is compatible with observations for a range of values of c_infinity (the value of the sound speed at late times) on which structure formation depends. In particular, we obtain an upper bound of c_infinity^2 leq 0.009 at 95% confidence level, meaning that the LambdaCDM model, for which c_infinity^2 = 0, is a good fit to the data, while the posterior probability distribution peaks at the value c_infinity^2=10^(-4) . Finally, we study the time dependence of the deviation from LambdaCDM via a tomographic analysis using a mock redshift distribution and we find that the largest deviation is for low-redshift sources, suggesting that future low-z surveys will be best suited to constrain UDM models.

CMB-Galaxy correlation in Unified Dark Matter Scalar Field Cosmologies

PIATTELLA O;
2011-01-01

Abstract

We present an analysis of the cross-correlation between the CMB and the large-scale structure (LSS) of the Universe in Unified Dark Matter (UDM) scalar field cosmologies. We work out the predicted cross-correlation function in UDM models, which depends on the speed of sound of the unified component, and compare it with observations from six galaxy catalogues (NVSS, HEAO, 2MASS, and SDSS main galaxies, luminous red galaxies, and quasars). We sample the value of the speed of sound and perform a likelihood analysis, finding that the UDM model is as likely as the LambdaCDM, and is compatible with observations for a range of values of c_infinity (the value of the sound speed at late times) on which structure formation depends. In particular, we obtain an upper bound of c_infinity^2 leq 0.009 at 95% confidence level, meaning that the LambdaCDM model, for which c_infinity^2 = 0, is a good fit to the data, while the posterior probability distribution peaks at the value c_infinity^2=10^(-4) . Finally, we study the time dependence of the deviation from LambdaCDM via a tomographic analysis using a mock redshift distribution and we find that the largest deviation is for low-redshift sources, suggesting that future low-z surveys will be best suited to constrain UDM models.
2011
http://dx.doi.org/10.1088/1475-7516/2011/03/039
UNIFIED DARK MATTER; INTEGRATED SACHS-WOLFE EFFECT; LARGE SCALE STRUCTURE POWER SPECTRUM
Daniele, Bertacca; Alvise, Raccanelli; Piattella, O; Davide, Pietrobon; Nicola, Bartolo; Sabino, Matarrese; Tommaso, Giannantonio
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Utilizza questo identificativo per citare o creare un link a questo documento: https://hdl.handle.net/11383/2125200
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