Determining the Hubble Constant without the Sound Horizon: A 3.6\% Constraint on H0 from Galaxy Surveys, CMB Lensing and Supernovae

Abstract

Many theoretical resolutions to the so-called "Hubble tension" rely on modifying the sound horizon at recombination, rs, and thus the acoustic scale used as a standard ruler in the cosmic microwave background (CMB) and large scale structure (LSS) datasets. As shown in a number of recent works, these observables can also be used to compute rs-independent constraints on H0 by making use of the horizon scale at matter-radiation equality, k eq, which has different sensitivity to high redshift physics than rs. As such, rs- and k eq-based measurements of H0 (within a framework) may differ if there is new physics present pre-recombination. In this work, we present the tightest constraints on the latter from current data, finding H0=64.8+2.2-2.5 at 68% CL (in km\,s-1Mpc-1 units) from a combination of BOSS galaxy power spectra, Planck CMB lensing, and the newly released Pantheon+ supernova constraints, as well as physical priors on the baryon density, neutrino mass, and spectral index. The BOSS and Planck measurements have different degeneracy directions, leading to the improved combined constraints, with a bound of H0 = 67.1+2.5-2.9 (63.6+2.9-3.6) from BOSS (Planck) alone. The results show some dependence on the neutrino mass bounds, with the constraint broadening to H0 = 68.0+2.9-3.2 if we instead impose a weak prior on Σ m from terrestrial experiments, or shifting to H0 = 64.62.4 if the neutrino mass is fixed to its minimal value. Even without dependence on the sound horizon, our results are in ≈ 3σ tension with those obtained from the Cepheid-calibrated distance ladder, which begins to cause problems for new physics models that vary H0 by changing acoustic physics or the expansion history immediately prior to recombination.