Recombination-independent determination of the sound horizon and the Hubble constant from BAO

Abstract

The Hubble tension and attempts to resolve it by modifying the physics of (or at) recombination motivate finding ways to determine H0 and the sound horizon at the epoch of baryon decoupling r d in ways that neither rely on a recombination model nor on late-time Hubble data. In this work, we investigate what one can learn from the current and future BAO data when treating r d and H0 as independent free parameters. It is well known that BAO gives exquisite constraints on the product r dH0. We show here that imposing a moderate prior on m h2 breaks the degeneracy between r d and H0. Using the latest BAO data, including the recently released eBOSS DR16, along with a m h2 prior based on the Planck best fit model, we find r d =143.7 2.7 Mpc and H0 = 69.6 1.8 km/s/Mpc. BAO data therefore prefers somewhat lower r d and higher H0 than those inferred from Planck data in a model. We find similar values when combing BAO with the Pantheon supernovae, DES galaxy weak lensing, Planck or SPTPol CMB lensing and the cosmic chronometers data. We perform a forecast for DESI and find that, when aided with a moderate prior on m h2, DESI will measure r d and H0 without assuming a recombination model with an accuracy surpassing the current best estimates from Planck.