Early- and Late-Time Modifications to ΛCDM: Implications for the Hubble Tension

Abstract

We investigate an extension of ΛCDM in which a fraction of cold Dark Matter (DM) decays into invisible dark radiation (DR) around the radiation-matter equality epoch, together with a non-standard dark energy (DE) equation of state characterized by w0. The decaying DM component modifies the early expansion history and reduces the sound horizon at baryon drag, while the DE alters the expansion rate at the late times. A comprehensive analysis combining Planck 2018+ACT DR6+DESI DR2+CMB lensing datasets has been carried out to explore the viability of this framework in addressing the H0 tension. This model yields a Hubble constant of H0 = 69.83 0.98~km\,s-1\,Mpc-1, reducing the discrepancy with SH0ES measurement to 2.2σ and local distance network measurement (H0DN) to 2.9σ. Further, considering SH0ES and Pantheon+, the inferred value of the Hubble constant becomes H0 = 70.20 0.66~km\,s-1\,Mpc-1. The Bayesian evidence suggests that this framework offers a fit to the relevant cosmological datasets at a statistically similar level as ΛCDM. It is observed that correlated early- and late-time modifications to the cosmological expansion history provide a more effective route to reducing the H0 tension than either class of modification alone.