Galaxy correlations and the BAO in a void universe: structure formation as a test of the Copernican Principle
Journal Article
19
Permanent link to this Item
Authors
Journal Title
Journal of Cosmology and Astroparticle Physics
Link to Journal
Journal ISSN
Volume Title
Publisher
IOP Publishing
Publisher
University of Cape Town
License
Series
Abstract
A suggested solution to the dark energy problem is the void model, where accelerated
expansion is replaced by Hubble-scale inhomogeneity. In these models, density
perturbations grow on a radially inhomogeneous background. This large scale inhomogeneity
distorts the spherical Baryon Acoustic Oscillation feature into an ellipsoid which implies
that the bump in the galaxy correlation function occurs at different scales in the radial and
transverse correlation functions. We compute these for the first time, under the approximation
that curvature gradients do not couple the scalar modes to vector and tensor modes. The
radial and transverse correlation functions are very different from those of the concordance
model, even when the models have the same average BAO scale. This implies that if void
models are fine-tuned to satisfy average BAO data, there is enough extra information in the
correlation functions to distinguish a void model from the concordance model. We expect
these new features to remain when the full perturbation equations are solved, which means
that the radial and transvers.
Description
Reference:
February, S., Clarkson, C., & Maartens, R. (2013). Galaxy correlations and the BAO in a void universe: structure formation as a test of the Copernican Principle. Journal of Cosmology and Astroparticle Physics, 2013(03), 023.