Neutrino mass constraints in interacting dark energy models after DESI DR2

Abstract

Recent DESI observations indicate a deviation from the ΛCDM model, showing a preference for dynamical dark energy and thereby relaxing the upper limit on the neutrino mass within this framework. This deviation can also be explained by the presence of an interaction between dark energy and dark matter. In this work, we investigate the cosmological upper bounds on the total neutrino mass (Σ mν) across four different interacting dark energy (IDE) models. The present analysis employs the latest DESI baryon acoustic oscillation, cosmic microwave background, and type Ia supernova datasets. These results demonstrate that the upper bounds on Σ mν exhibit profound sensitivity to the specific phenomenological formulation of the interaction term. While the IΛCDM2 model (Q H ρc) substantially relaxes the stringent upper limit (Σ mν < 0.129 eV at 95% confidence level), notably the IΛCDM3 model (Q H0 ρde), severely compresses the allowed parameter space, yielding a highly restrictive bound of Σ mν < 0.051 eV. Furthermore, rigorous goodness-of-fit evaluations utilizing the Deviance Information Criterion and Δχ2MAP indicate that the current observational data statistically favor these mass-suppressing IDE models. This establishes an exacerbated statistical tension between the observationally preferred IDE scenarios and the normal hierarchy lower bound ( 0.06 eV) determined by terrestrial neutrino oscillation experiments.