Modelling redshift-space distortion in the post-reionization HI 21-cm power spectrum

Abstract

The post-reionization HI 21-cm signal is an excellent candidate for precision cosmology, this however requires accurate modelling of the expected signal. Sarkar et al. (2016) have simulated the real space HI 21-cm signal, and have modelled the HI power spectrum as P HI(k)=b2 P(k) where P(k) is the dark matter power spectrum and b(k) is a (possibly complex) scale dependent bias for which fitting formulas have been provided. This paper extends these simulations to incorporate redshift space distortion and predict the expected redshift space HI 21-cm power spectrum Ps HI(k,k) using two different prescriptions for the HI distributions and peculiar velocities. We model Ps HI(k,k) assuming that it is the product of P HI(k)=b2 P(k) with a Kaiser enhancement term and a Finger of God (FoG) damping which has σp the pair velocity dispersion as a free parameter. Considering several possibilities for the bias and the damping profile, we find that the models with a scale dependent bias and a Lorentzian damping profile best fit the simulated Ps HI(k,k) over the entire range 1 z 6. The best fit value of σp falls approximately as (1+z)-m with m=2 and 1.2 respectively for the two different prescriptions. The model predictions are consistent with the simulations for k < 0.3 \, Mpc-1 over the entire z range for the monopole Ps0(k), and at z 3 for the quadrupole Ps2(k). At z 4 the models underpredict Ps2(k) at large k, and the fit is restricted to k < 0.15 \, Mpc-1.