Cosmological Tensions and the Transitional Planck Mass Model

Abstract

In this followup analysis, we update previous constraints on the Transitional Planck Mass (TPM) modified gravity model using the latest version of EFTCAMB and provide new constraints using SPT and Planck anisotropy data along with Planck CMB lensing, BAO, SNe Ia, and an H0 prior from local measurements. We find that large shifts in the Planck mass lead to large suppression of power on small scales that is disfavored by both SPT and Planck. Using only SPT TE-EE data, this suppression of power can be compensated for by an upward shift of the scalar index to ns = 1.003 0.016 resulting in H0 = 71.94+0.86-0.85 kms-1Mpc-1 and a 7\% shift in the Planck mass. Including Planck TT ≤ 650 and Planck TE-EE data restricts the shift to be <5\% at 2σ with H0 = 70.65 0.66 kms-1Mpc-1. Excluding the H0 prior, SPT and Planck data constrain the shift in the Planck mass to be <3\% at 2σ with a best-fit value of 0.04\%, consistent with the limit. In this case H0 = 69.09+0.69-0.68 kms-1Mpc-1, which is partially elevated by the dynamics of the scalar-field in the late universe. This differs from EDE models that prefer higher values of H0 when high Planck TT data are excluded. We additionally constrain TPM using RSD data from BOSS DR 12 and cosmic shear, galaxy-galaxy lensing, and galaxy clustering data from DES Y1 finding both disfavor transitions close to recombination, but earlier Planck mass transitions are allowed.