Modifying ΛCDM dynamics via out-of-equilibrium axions: reconciling SH0ES and DESI H0 values

Abstract

We investigate late-Universe dynamics in which the dark matter component is described by axion particles. The proposed framework departs from the standard ΛCDM paradigm due to a small fraction of axions driving the system away from thermal equilibrium. We analyze the evolution of the axion energy density using both a kinetic and a classical field approach, yielding an identical macroscopic evolution equation for the dark matter density. The resulting scenario modifies ΛCDM dynamics in the late Universe (specifically at z 1), while asymptotically recovering the standard baseline at earlier cosmic epochs. We compare the theoretical predictions of our formulation against a comprehensive suite of late-Universe datasets. Our statistical analysis reveals that when the SH0ES local calibration is included, the collisional axion model becomes significantly favored over ΛCDM, yielding a best-fit Hubble constant of H0 73~ km\,s-1\,Mpc-1. Ultimately, this cosmological scenario successfully accommodates local distance-ladder measurements while maintaining excellent agreement with Baryon Acoustic Oscillation data from the DESI Collaboration.