Constraints on the sum of the neutrino masses in dynamical dark energy models with w(z) ≥ -1 are tighter than those obtained in

Abstract

We explore cosmological constraints on the sum of the three active neutrino masses M in the context of dynamical dark energy (DDE) models with equation of state (EoS) parametrized as a function of redshift z by w(z)=w0+wa\,z/(1+z), and satisfying w(z)≥-1 for all z. We perform a Bayesian analysis and show that, within these models, the bounds on M do not degrade with respect to those obtained in the case; in fact the bounds are slightly tighter, despite the enlarged parameter space. We explain our results based on the observation that, for fixed choices of w0\,,wa such that w(z)≥-1 (but not w=-1 for all z), the upper limit on M is tighter than the limit because of the well-known degeneracy between w and M. The Bayesian analysis we have carried out then integrates over the possible values of w0-wa such that w(z)≥-1, all of which correspond to tighter limits on M than the limit. We find a 95\% confidence level (C.L.) upper bound of M<0.13\,eV. This bound can be compared with M<0.16\,eV at 95\%~C.L., obtained within the model, and M<0.41\,eV at 95\%~C.L., obtained in a DDE model with arbitrary EoS (which allows values of w < -1). Contrary to the results derived for DDE models with arbitrary EoS, we find that a dark energy component with w(z)≥-1 is unable to alleviate the tension between high-redshift observables and direct measurements of the Hubble constant H0. Finally, in light of the results of this analysis, we also discuss the implications for DDE models of a possible determination of the neutrino mass hierarchy by laboratory searches. (abstract abridged)