Exponential f(R) cosmology with massive neutrinos as a dynamical dark energy framework
Abstract
The exponential f(R) gravity model provides a theoretically well-motivated extension of General Relativity, introducing a modified gravitational dynamics at late times consistent with a dynamical dark energy scenario, while recovering the ΛCDM-like regime at high redshifts with a smooth transition. Using a Bayesian Markov Chain Monte Carlo (MCMC) analysis, we constrain the parameters of the exponential f(R) model in combination with the total neutrino mass Σ mν, employing the latest measurements from cosmic chronometers, the DESI DR2 BAO data, the CMB acoustic scale, and the Pantheon+ supernovae compilation, comparing the results with the ΛCDM and the w0waCDM models. Our results show that the exponential f(R) model remains consistent with current observations while slightly alleviating the Hubble tension and the neutrino mass problem relative to ΛCDM, although the constraints on Σ mν are tighter than those obtained for the phenomenological w0waCDM scenario. These results indicate that the interplay between modified gravity and neutrino physics in the late Universe may offer a viable framework for further investigation of cosmological tensions.
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