Probing Early Modification of Gravity with Planck, ACT and SPT

Abstract

We consider a model of early modified gravity (EMG) that was recently proposed as a candidate to resolve the Hubble tension. The model consists in a scalar field σ with a non-minimal coupling (NMC) to the Ricci curvature of the form F(σ) = Mpl2+σ2 and an effective mass induced by a quartic potential V(σ) = λ σ4/4. We present the first analyses of the EMG model in light of the latest ACT DR4 and SPT-3G data in combination with full Planck data, and find a 2σ preference for a non-zero EMG contribution from a combination of primary CMB data alone, mostly driven by ACT DR4 data. This is different from popular 'Early Dark Energy' models, which are detected only when the high- information from Planck temperature is removed. We find that the NMC plays a key role in controlling the evolution of density perturbations that is favored by the data over the minimally coupled case. Including measurements of supernovae luminosity distance from Pantheon+, baryonic acoustic oscillations and growth factor from BOSS, and CMB lensing of Planck leaves the preference unaffected. In the EMG model, the tension with SH0ES is alleviated from 6σ to 3σ. Further adding SH0ES data rise the detection of the EMG model above 5σ.