Cosmological Measurements from Angular Power Spectra Analysis of BOSS DR12 Tomography

Abstract

We constrain cosmological parameters by analysing the angular power spectra of the Baryon Oscillation Spectroscopic Survey DR12 galaxies, a spectroscopic follow-up of around 1.3 million SDSS galaxies over 9,376 deg2 with an effective volume of 6.5 (Gpc h-1)3 in the redshift range 0.15 ≤ z < 0.80. We split this sample into 13 tomographic bins ( z = 0.05); angular power spectra were calculated using a Pseudo-C estimator, and covariance matrices were estimated using log-normal simulated maps. Cosmological constraints obtained from these data were combined with constraints from Planck CMB experiment as well as the JLA supernovae compilation. Considering a wCDM cosmological model measured on scales up to kmax = 0.07h Mpc-1, we constrain a constant dark energy equation-of-state with a 4\% error at the 1-σ level: w0 = -0.993+0.046-0.043, together with m = 0.330 0.012, b = 0.0505 0.002, S8 σ8 m/0.3 = 0.863 0.016, and h = 0.661 0.012. For the same combination of datasets, but now considering a model with massive neutrinos and the same scale cut, we find: m = 0.328 0.009, b = 0.05017+0.0009-0.0008, S8 = 0.862 0.017, and h = 0.663+0.006-0.007 and a 95\% credible interval (CI) upper limit of Σ m < 0.14 eV for a normal hierarchy. These results are competitive if not better than standard analyses with the same dataset, and demonstrate this should be a method of choice for future surveys, opening the door for their full exploitation in cross-correlations probes.