Did the Universe Reheat After Recombination?

Abstract

A key assumption of the standard cosmological model is that the temperature of the cosmic microwave background (CMB) radiation scales with cosmological redshift z as T CMB(z) (1+z) at all times after recombination at z 1090. However, this assumption has only been precisely tested at z 3. Here, we consider cosmological models with post-recombination reheating (PRR), in which the CMB monopole temperature abruptly increases due to energy injection after last scattering. Such a scenario can potentially resolve tensions between inferences of the current cosmic expansion rate (the Hubble constant, H0). We consider an explicit model in which a metastable sub-component of dark matter (DM) decays to Standard Model photons, whose spectral energy distribution is assumed to be close to that of the CMB blackbody. A fit to Planck CMB anisotropy, COBE/FIRAS CMB monopole, and SH0ES distance-ladder measurements yields H0 = 71.2 1.1 km/s/Mpc, matter fluctuation amplitude S8 = 0.774 0.018, and CMB temperature increase δ T CMB = 0.109+0.033-0.044 K, which is sourced by DM decay at z 10. However, matter density constraints from baryon acoustic oscillation and supernovae data highly constrain this scenario, with a joint fit to all datasets yielding H0 = 68.69 0.35 km/s/Mpc, S8 = 0.8035 0.0081, and δ T CMB < 0.0342 K (95% CL upper limit). These bounds can be weakened if additional dark relativistic species are present in the early universe, yielding higher H0. We conclude that current data disfavor models with significant PRR solely through its impact on background and linear-theory observables, completely independent of CMB spectral distortion constraints. However, a small amount of such energy injection could play a role in restoring cosmological concordance.