On the Hubble constant tension in the SNe Ia Pantheon sample

Abstract

The Hubble constant (H0) tension between Type Ia Supernovae (SNe Ia) and Planck measurements ranges from 4 to 6 σ. To investigate this tension, we estimate H0 in the and w0waCDM models by dividing the Pantheon sample, the largest compilation of SNe Ia, into 3, 4, 20 and 40 bins. We fit the extracted H0 values with a function mimicking the redshift evolution: g(z)=H0(z)=H0/(1+z)α, where α indicates an evolutionary parameter and H0=H0 at z=0. We set the absolute magnitude of SNe Ia so that H0=73.5\,\, km s-1\,Mpc-1, and we fix fiducial values for 0m CDM=0.298 and 0mw0waCDM=0.308. We find that H0 evolves with redshift, showing a slowly decreasing trend, with α coefficients consistent with zero only from 1.2 to 2.0 σ. Although the α coefficients are compatible with 0 in 3 σ, this however may affect cosmological results. We measure locally a variation of H0(z=0)-H0(z=1)=0.4\, km s-1\,Mpc-1 in 3 and 4 bins. Extrapolating H0(z) to z=1100, the redshift of the last scattering surface, we obtain values of H0 compatible in 1 σ with Planck measurements independently of cosmological models and number of bins we investigated. Thus, we have reduced the H0 tension from 54\% to 72\% for the and w0waCDM models, respectively. If the decreasing trend of H0(z) is real, it could be due to astrophysical selection effects or to modified gravity.