Sound-Horizon-Agnostic Inference of the Hubble Constant and Neutrino Mass from BAO, CMB Lensing, and Galaxy Weak Lensing and Clustering

Abstract

We present a sound-horizon-agnostic determination of the Hubble constant, H0, by combining DESI DR2 baryon acoustic oscillation (BAO) data with the latest cosmic microwave background (CMB) lensing measurements from Planck, ACT, and SPT-3G, the angular size of the CMB acoustic scale, Dark Energy Survey Year-3 (3×2-pt) galaxy weak lensing and clustering correlations, and the Pantheon+ supernova sample. In this analysis, The sound horizon at the drag epoch, rd, is treated as a free parameter. By combining uncalibrated comoving distances from BAO and supernovae with constraints on the matter density m h2 from CMB and galaxy lensing/clustering, we break the rd-H0 degeneracy and obtain H0 = 70.0 1.7 km/s/Mpc when the sum of the neutrino masses is fixed at m = 0.06 eV. With an informative prior on the amplitude of primordial fluctuations, As, we find H0 = 70.03 0.97 km/s/Mpc. Allowing m to vary, we find that the neutrino mass is weakly constrained and strongly prior-dependent. Consequently, the inferred H0 is sensitive to the choice of the m prior, with a uniform prior biasing results toward larger neutrino masses and higher H0, while a logarithmic prior reduces this bias significantly. Forecasts for the completed DESI BAO program, combined with Simons-Observatory-like CMB lensing, next-generation 3×2-pt data, and expanded supernova samples predict σ(H0) 0.67 km/s/Mpc with fixed m, and σ(H0) 1.1 km/s/Mpc with m < 0.133 (<0.263) eV at 68% (95%) CL when m is varied.