Inhomogeneous Cosmology Redux

Abstract

An alternative to the postulate of dark energy required to explain the accelerated expansion of the universe is to adopt an inhomogeneous cosmological model to explain the supernovae data without dark energy. We adopt a void cosmology model, based on the inhomogeneous Lema\itre-Tolman-Bondi solution of Einstein's field equations. The model can resolve observational anomalies in the CDM model, such as the discrepancy between the locally measured value of the Hubble constant, H0=73.24 1.74\, km\, s-1\, Mpc-1, and the H0=66.93 0.62\, km\, s-1\, Mpc-1 determined by the Planck satellite data and the CDM model, and the lithium 7 Li problem, which is a 5σ mismatch between the theoretical prediction for the 7 Li from big bang nucleosynthesis and the value that we observe locally today at z=0. The void model can also resolve the tension between the number of massive clusters derived from the Sunyaev-Zel'dovich effect by the Planck satellite and the number expected from the CMB anisotropies, and the CMB weak lensing anomaly observed in the Planck data. The cosmological Copernican principle and the time and position today coincidence conundrums in the CDM and void cosmological models are discussed.