Testing anisotropic Hubble expansion
Abstract
The cosmological principle asserting the large-scale uniformity of the Universe is a testable assumption of the standard cosmological model. We explore the constraints on anisotropic expansion provided by measuring directional variation in the Hubble constant, H0, derived from differential zeropoint measurements of the Tully-Fisher distance estimator. We fit various models for directional variation in H0 using the Tully-Fisher dataset from the all-sky Cosmicflows-4 catalog. The best-fit dipole variation has an amplitude of 0.063 0.016 mag in the direction (,b) = (142 30, 52 10). If this were due to anisotropic expansion it would imply a 3% variation in H0, corresponding to H0 = 2.10 0.53 km/s/Mpc if H0 = 70 km/s/Mpc, with a significance of 3.9σ. A model that includes this H0 dipole is only weakly favored relative to a model with a constant H0 and a bulk motion of the volume sampled by Cosmicflows-4 that is consistent with the standard cosmology. However, we show that with the expected Tully-Fisher data from the WALLABY and DESI surveys it should be possible to detect a 1% H0 dipole anisotropy at 5.8σ confidence and to distinguish it from the typical bulk flow predicted by over the volume of these surveys.
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