The Serendipitous Axiodilaton: A Self-Consistent Recombination-Era Solution to the Hubble Tension
Abstract
Axio-dilaton cosmology provides a minimal benchmark model for both Dark Matter (DM) and Dark Energy (DE) that is well motivated by fundamental physics. The axion and dilaton arise as pseudo-Goldstone modes of symmetries that predict particle masses depend on the dilaton, and therefore to evolve cosmologically, leading to correlated modifications of recombination physics, the sound horizon, and late-time expansion and growth histories. We confront this model with Planck 2018 temperature, polarisation, and lensing data, SPT-3G high- measurements, DESI DR2 BAO, and Pantheon+ supernovae, assuming that the axion makes up all of the dark matter and that the dilaton plays the role of a dark energy field. We find that it fits the data somewhat better than cosmology, with the 2 lowered by 7 for three additional parameters, and significantly raises the inferred Hubble constant to H0 69.2\,km\,s-1\,Mpc-1, reducing the Hubble tension to 3σ and thereby allowing a joint fit of CMB and SH0ES data. The model fits this enlarged data set as well as the w0wa model with an electron mass modified by hand at recombination, though it does so with calculable dynamics. Axio-dilaton self-interactions robustly fake a phantom equation of state in DESI measurements. There is a sting: cosmology prefers dilaton-matter couplings |g| 10-2-10-1, which are large enough to have been detected in solar-system tests of General Relativity. These results show how axio-dilatons can provide a viable cosmology preferred by current data at surprisingly large couplings, within a framework that links dark energy, dark matter, and time-dependent particle masses in a coherent way. They suggest both new observable signals and new theoretical directions, aimed at resolving the apparent inconsistency with non-cosmological observations.
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