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Biased tracers in redshift space in the EFTofLSS with exact time dependence

Yaniv Donath, Leonardo Senatore

2020Journal of Cosmology and Astroparticle Physics46 citationsDOIOpen Access PDF

Abstract

We study the effect of the Einstein-de Sitter (EdS) approximation on the one-loop power spectrum of galaxies in redshift space in the Effective Field Theory of Large-Scale Structure. The dark matter density perturbations and velocity divergence are treated with exact time dependence. Splitting the density perturbation into its different temporal evolutions naturally gives rise to an irreducible basis of biases. While, as in the EdS approximation, at each time this basis spans a seven-dimensional space, this space is a slightly different one, and the difference is captured by a single calculable time- and vec k-dependent function. We then compute the redshift-space galaxy one-loop power spectrum with the EdS approximation (P<sup>EdS-approx</sup>) and without (P<sup>Exact</sup>). For the monopole we find P<sub>0</sub><sup>Exact</sup>/P<sub>0</sub>Ed<sup>S-approx</sup>~ 1.003 and for the quadrupole P<sub>2</sub><sup>Exact</sup>/P<sub>2</sub><sup>EdS-approx</sup>~ 1.007 at z=0.57, and sharply increasing at lower redshifts. Finally, we show that a substantial fraction of the effect remains even after allowing the bias coefficients to shift within a physically allowed range. This suggests that the EdS approximation can only fit the data to a level of precision that is roughly comparable to the precision of the next generation of cosmological surveys. Furthermore, we find that implementing the exact time dependence formalism is not demanding and is easily applicable to data. Both of these points motivate a direct study of this effect on the cosmological parameters.

Topics & Concepts

PhysicsRedshiftApproxSpectral densityAstrophysicsGalaxyCosmological perturbation theoryCosmologyMathematical physicsStatisticsComputer scienceMathematicsOperating systemCosmology and Gravitation TheoriesGalaxies: Formation, Evolution, PhenomenaBlack Holes and Theoretical Physics