CMB signature of a super-Hubble inhomogeneity in the gravitational field enclosing the present Hubble volume

TL;DR

This paper proposes that a super-Hubble scale inhomogeneity in the gravitational field could explain the observed hemispherical asymmetry in the CMB temperature fluctuations, providing a potential large-scale structure signature.

Contribution

It introduces a model linking super-Hubble inhomogeneities to CMB anisotropy asymmetries, highlighting non-diagonal covariance entries as observational signatures.

Findings

Non-diagonal covariance entries are sensitive to inhomogeneity strength.

Inhomogeneity causes a power asymmetry with maximal effect at 90° to the dipole axis.

Predicted asymmetry axis aligns with observed CMB asymmetry direction.

Abstract

Repeated studies of the CMB based on WMAP data have revealed an apparent asymmetry in the distribution of temperature fluctuations over the celestial sphere. The studies indicate that the amplitudes of temperature fluctuations are higher in one hemisphere than in the other. We consider whether this asymmetry could originate from a large scale inhomogeneity in the gravitational field enclosing the present Hubble volume. We examine what effect the presence of an inhomogeneity in the gravitational field of size larger than the present Hubble radius would have on the temperature distribution of the CMB and start eliciting its observational signature in the CMB power spectrum. The covariance function contains, in addition to the diagonal entries of the conventional CMB temperature anisostropy power spectrum, non-diagonal entries. We find that specific non-diagonal entries of the covariance function are sensitive to the strength of the inhomogeneity, while the diagonal entries are not. These non-diagonal entries, which are not present in the case of a homogeneous background geometry, are observational signatures of a large-scale inhomogeneity in the background geometry of the universe. Furthermore, we find that an inhomogeneity in the gravitational potential of super-Hubble size would yield a power asymmetry in the CMB with maximal asymmetry at an angle of 90 degrees to the CMB dipole axis. The axis of the CMB power asymmetry was recently estimated by Eriksen et. al. to be located at angles between 83 and 96 degrees to the CMB dipole axis, which is consistent with the prediction of our model. This implies that the location of the observed power asymmetry in the CMB sky could be accounted for by a large-scale inhomogeneity in the gravitational field enclosing the present Hubble volume.