Beyond BAO: improving cosmological constraints from BOSS with measurement of the void-galaxy cross-correlation

Abstract

We present a measurement of the anisotropic void-galaxy cross-correlation function in the CMASS galaxy sample of the BOSS DR12 data release. We perform a joint fit to the data for redshift space distortions (RSD) due to galaxy peculiar velocities and anisotropies due to the Alcock-Paczynski (AP) effect, for the first time using a velocity field reconstruction technique to remove the complicating effects of RSD in the void centre positions themselves. Fits to the void-galaxy function give a 1% measurement of the AP parameter combination DA(z)H(z)/c = 0.4367 0.0045 at redshift z=0.57, where DA is the angular diameter distance and H the Hubble parameter, exceeding the precision obtainable from baryon acoustic oscillations (BAO) by a factor of ~3.5 and free of systematic errors. From voids alone we also obtain a 10% measure of the growth rate, fσ8(z=0.57)=0.5010.051. The parameter degeneracies are orthogonal to those obtained from galaxy clustering. Combining void information with that from BAO and galaxy RSD in the same CMASS sample, we measure DA(0.57)/rs=9.383 0.077 (at 0.8% precision), H(0.57)rs=(14.05 0.14)\;103 kms-1Mpc-1 (1%) and fσ8=0.4530.022 (4.9%), consistent with cosmic microwave background (CMB) measurements from Planck. These represent a factor 2 improvement in precision over previous results through the inclusion of void information. Fitting a flat cosmological constant model to these results in combination with Planck CMB data, we find up to an 11% reduction in uncertainties on H0 and m compared to use of the corresponding BOSS consensus values. Constraints on extended models with non-flat geometry and a dark energy of state that differs from w=-1 show an even greater improvement.