Reconstruction of A Scale-Dependent Gravitational Phase Transition (2306.14014v1)

Abstract: In this work we extend our earlier phenomenological model for a gravitational phase transition (GPT) and its generalization to early times by letting the modifications in the linearly-perturbed Einstein equations be scale-dependent. These modifications are characterized as deviations of the parameters $\mu(z,k)$ and $\gamma(z,k)$ from their values in general relativity (GR). The scale-dependent amplitudes of modified $\mu(z,k)$ and $\gamma(z,k)$ and the parameters defining the phase transition, along with the standard cosmological parameters, are measured by various data combinations. Out of the perturbation parameters, we construct gravity eigenmodes which represent patterns of perturbations best detectable by data. We detect no significant deviation from GR in these parameters. However, the larger parameter space produced due to the new degrees of freedom allows for the reconciliation of various datasets which are in tension in $\Lambda$CDM. In particular, we find $H_0=71.9\pm 9.2$ from anisotropies of the Cosmic Microwave Background as measured by Planck and various measurements of the Baryonic Acoustic Oscillations, in agreement with local Hubble measurements. We also find that the $\sigma_8$ tension between the measurements of Dark Energy Survey and Planck is reduced to less than $1\sigma$.