The redshift dependence of Alcock-Paczynski effect: cosmological constraints from the current and next generation observations

Abstract

The tomographic Alcock-Paczynski (AP) test is a robust large-scale structure (LSS) measurement that receives little contamination from the redshift space distortion (RSD). It has placed tight cosmological constraints by using small and intermediate clustering scales of the LSS data. However, previous works have neglected the cross-correlation among different redshift bins, which could cause the statistical uncertainty being underestimated by 20\%. In this work, we further improve this method by including this multi-redshifts full correlation. We apply it to the SDSS DR12 galaxies sample and find out that, for , the combination of AP with the Planck+BAO dataset slightly reduces (within 1-σ) m to 0.3040.007 (68.3\% CL). This then leads to a larger H0 and also mildly affects b h2, ns and the derived parameters z*, r*, zre but not τ, As and σ8. For the flat wCDM model, our measurement gives m=0.301 0.010 and w=-1.090 0.047, where the additional AP measurement reduces the error budget by 25\%. When including more parameters into the analysis, the AP method also improves the constraints on k, Σ mμ, N eff by 20-30\%. Early universe parameters such as dns/d lnk and r, however, are unaffected. Assuming the dark energy equation of state w=w0+wa z1+z, the Planck+BAO+SNIa+H0+AP datasets prefer a dynamical dark energy at ≈1.5 σ CL. Finally, we forecast the cosmological constraints expected from the DESI galaxy survey and find that combining AP with CMB+BAO method would improve the w0-wa constraint by a factor of 10.