The WiggleZ Dark Energy Survey: the selection function and z=0.6 galaxy power spectrum

TL;DR

This paper presents a highly accurate measurement of the galaxy power spectrum at redshift 0.6 from the WiggleZ survey, analyzing large-scale structure, redshift-space distortions, and growth rate to test cosmological models.

Contribution

It provides a detailed construction of the survey selection function and measures the galaxy power spectrum with unprecedented precision, including analysis of growth rate and redshift-space distortions.

Findings

Power spectrum measured with 5% accuracy in wavenumber bands

Growth rate at z=0.78 matches LCDM predictions

Large-scale shape consistent with CMB-derived matter and baryon densities

Abstract

We report one of the most accurate measurements of the three-dimensional large-scale galaxy power spectrum achieved to date, using 56,159 redshifts of bright emission-line galaxies at effective redshift z=0.6 from the WiggleZ Dark Energy Survey at the Anglo-Australian Telescope. We describe in detail how we construct the survey selection function allowing for the varying target completeness and redshift completeness. We measure the total power with an accuracy of approximately 5% in wavenumber bands of dk=0.01 h/Mpc. A model power spectrum including non-linear corrections, combined with a linear galaxy bias factor and a simple model for redshift-space distortions, provides a good fit to our data for scales k < 0.4 h/Mpc. The large-scale shape of the power spectrum is consistent with the best-fitting matter and baryon densities determined by observations of the Cosmic Microwave Background radiation. By splitting the power spectrum measurement as a function of tangential and radial wavenumbers we delineate the characteristic imprint of peculiar velocities. We use these to determine the growth rate of structure as a function of redshift in the range 0.4 < z < 0.8, including a data point at z=0.78 with an accuracy of 20%. Our growth rate measurements are a close match to the self-consistent prediction of the LCDM model. The WiggleZ Survey data will allow a wide range of investigations into the cosmological model, cosmic expansion and growth history, topology of cosmic structure, and Gaussianity of the initial conditions. Our calculation of the survey selection function will be released at a future date via our website wigglez.swin.edu.au.