Updated fundamental constant constraints from Planck 2018 data and possible relations to the Hubble tension

Abstract

We present updated constraints on the variation of the fine structure constant, α EM, and effective electron rest mass, m e, during the cosmological recombination era. These two fundamental constants directly affect the ionization history at redshift z 1100 and thus modify the temperature and polarisation anisotropies of the cosmic microwave background (CMB) measured precisely with Planck . The constraints on α EM tighten slightly due to improved Planck 2018 polarisation data but otherwise remain similar to previous CMB analysis. However, a comparison with the 2015 constraints reveals a mildly discordant behaviour for m e, which from CMB data alone is found below its local value. Adding baryon acoustic oscillation data brings m e back to the fiducial value, m e=(1.00780.0067) m e,0, and also drives the Hubble parameter to H0=69.1 1.2 [in units of km \, s-1 \, Mpc-1 ]. Further adding supernova data yields m e=(1.01900.0055) m e,0 with H0=71.240.96. We perform several comparative analyses using the latest cosmological recombination calculations to further understand the various effects. Our results indicate that a single-parameter extension allowing for a slightly increased value of m e ( 3.5σ above m e,0) could play a role in the Hubble tension.