Changing the prior: absolute neutrino mass constraints in nonlocal gravity

Abstract

Prior change is discussed in observational constraints studies of nonlocally modified gravity. In the latter, a model characterized by a modification of the form m2 R-2R to the Einstein-Hilbert action was compared against the base one in a Bayesian way. It was found that the competing modified gravity model is significantly disfavored (at 22 \,:\, 1 in terms of betting-odds) against given CMB+SNIa+BAO data, because of a dominant tension appearing in the H0 \,-\, M plan. We identify the underlying mechanism generating such a tension and show that it is mostly caused by the late-time, quite smooth, phantom nature of the effective dark energy described by the nonlocal model. We find possible solutions for it to be resolved and explore a given one that consists in extending the initial baseline from one massive neutrino eigenstate to three degenerate ones, whose absolute mass Σ m \, / \, 3 is allowed to take values within a reasonable prior interval. As a net effect, the absolute neutrino mass is inferred to be non-vanishing at 2 σ level, best-fitting at Σ m ≈ 0.21 \, eV, and the Bayesian tension disappears rendering the nonlocal gravity model statistically equivalent to , given recent CMB+SNIa+BAO data. We also discuss constraints from growth rate measurements f σ8 whose fit is found to be improved by a larger massive neutrino fraction as well. The -extended nonlocal model also prefers a higher value of H0 than , therefore in better agreement with local measurements.