Constraining spatial curvature with large-scale structure
Abstract
We analyse the clustering of matter on large scales in an extension of the concordance model that allows for spatial curvature. We develop a consistent approach to curvature and wide-angle effects on the galaxy 2-point correlation function in redshift space. In particular we derive the Alcock-Paczynski distortion of , which differs significantly from empirical models in the literature. A key innovation is the use of the `Clustering Ratio', which probes clustering in a different way to redshift-space distortions, so that their combination delivers more powerful cosmological constraints. We use this combination to constrain cosmological parameters, without CMB information. In a curved Universe, we find that (68\% CL). When the clustering probes are combined with low-redshift background probes -- BAO and SNIa -- we obtain a CMB-independent constraint on curvature: . We find no Bayesian evidence that the flat concordance model can be rejected. In addition we show that the sound horizon at decoupling is , in agreement with its measurement from CMB anisotropies. As a consequence, the late-time Universe is compatible with flat CDM and a standard sound horizon, leading to a small value of , {\em without} assuming any CMB information. Clustering Ratio measurements produce the only low-redshift clustering data set that is not in disagreement with the CMB, and combining the two data sets we obtain .
Keywords
Cite
@article{arxiv.2206.03059,
title = {Constraining spatial curvature with large-scale structure},
author = {Julien Bel and Julien Larena and Roy Maartens and Christian Marinoni and Louis Perenon},
journal= {arXiv preprint arXiv:2206.03059},
year = {2022}
}
Comments
40 pages; 13 figures; Version accepted by JCAP