The H0 tension: GN vs. N eff

Abstract

We investigate whether the 4.4σ tension on H0 between SH0ES 2019 and Planck 2018 can be alleviated by a variation of Newton's constant GN between the early and the late Universe. This changes the Hubble rate before recombination, similarly to adding N eff extra relativistic degrees of freedom. We implement a varying GN in a scalar-tensor theory of gravity, with a non-minimal coupling (M2+β φ2)R. If the scalar φ starts in the radiation era at an initial value φI 0.5~Mp and with β<0, a dynamical transition occurs naturally around the epoch of matter-radiation equality and the field evolves towards zero at late times. As a consequence, the H0 tension between SH0ES (2019) and Planck 2018+BAO slightly decreases, as in N eff models, to the 3.8σ level. We then perform a fit to a combined Planck, BAO and supernovae (SH0ES and Pantheon) dataset. When including local constraints on Post-Newtonian (PN) parameters, we find H0=69.08-0.71+0.6~km/s/Mpc and a marginal improvement of 2-3.2 compared to , at the cost of 2 extra parameters. In order to take into account scenarios where local constraints could be evaded, we also perform a fit without PN constraints and find H0=69.65-0.78+0.8~km/s/Mpc and a more significant improvement 2=-5.4 with 2 extra parameters. For comparison, we find that the N eff model gives H0=70.08-0.95+0.91~km/s/Mpc and 2=-3.4 at the cost of one extra parameter, which disfavors the limit just above 2σ, since N eff=0.34-0.16+0.15. Overall, our varying GN model performs similarly to the N eff model in respect to the H0 tension, if a physical mechanism to remove PN constraints can be implemented.