The galaxy power spectrum on the lightcone: deep, wide-angle redshift surveys and the turnover scale

Abstract

We derive expressions for the survey-window convolved galaxy power spectrum in real space for a full sky and deep redshift survey, but taking into account the geometrical lightcone effect. We investigate the impact of using the standard mean redshift approximation as a function of survey depth, and show that this assumption can lead to both an overall amplitude suppression and scale-dependent error when compared to the `true' spectrum. However, we also show that by using a carefully chosen `effective fixed-time', one can find a range of scales where the approximation to the full model is highly accurate, but only on a more restricted set of scales. We validate the theory by constructing dark matter and galaxy lightcone mock surveys from a large N-body simulation with a high cadence of snapshots. We do this by solving the light cone equation exactly for every particle, where the particle worldlines are obtained in a piecewise fashion with cubic interpolation between neighbouring snapshots. We find excellent agreement between our measurements and the theory ( 5\%) over scales (0.004 h Mpc-1 ≤ k ≤ 0.54 h Mpc-1) and for a variety of magnitude limits. Finally, we look to see how accurately we can measure the turnover scale of the galaxy power spectrum k0. Using the lightcone mocks we show that one can detect the turnover scale with a probability P ≥ 95\% in an all-sky catalogue limited to an apparent magnitude m lim 21. We also show that the detection significance would remain high for surveys with m lim22 and 20\% sky coverage.