Can the sound horizon-free measurement of H0 constrain early new physics?

Abstract

The sound horizon-independent H0 extracted by using galaxy clustering surveys data through, e.g., EFTofLSS or ShapeFit analyses, is considered to have the potential to constrain the early new physics responsible for solving the Hubble tension. Recent observations, e.g. DESI, have shown that the sound horizon-independent measurement of H0 is consistent with . In this work, we clarify some potential misuses and misinterpretations in these analyses. On the one hand, imposing some prior from other cosmological probes is often used to strengthen the constraints on the results, however, these priors are usually derived using the assumption of , it is not suitable to apply these so-called priors (e.g., the ns prior from CMB), which would bias the results, to early new physics because these early new physics are usually accompanied by shifts of the parameters. On the other hand, the constraints on H0 in the sound horizon-independent EFTofLSS analysis arise from not only the shape of the power spectrum (keq-based H0), but also the overall amplitude (when combined with CMB lensing observations) and the relative amplitudes of the BAO wiggles, thus besides keq other information may also play a role in constraining H0. We also make forecasts for an Euclid-like survey, which suggest that ongoing observations will also have difficulty constraining early new physics.