# Changing the prior: absolute neutrino mass constraints in nonlocal   gravity

**Authors:** Yves Dirian

arXiv: 1704.04075 · 2017-10-25

## TL;DR

This study investigates how extending the neutrino sector in a nonlocal gravity model can resolve tensions with cosmological data, leading to non-zero neutrino masses and improved parameter fits.

## Contribution

It introduces a neutrino extension in a nonlocal gravity model, demonstrating how it alleviates tensions and aligns with observational data, including neutrino mass constraints.

## Key findings

- Neutrino extension resolves the $H_0$ tension.
- Nonlocal gravity model with neutrinos fits data well.
- Neutrino mass inferred to be around 0.21 eV at 2 sigma.

## 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 $\sim m^2 R\Box^{-2}R$ to the Einstein-Hilbert action was compared against the base $\Lambda$CDM 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 $\Lambda$CDM given CMB+SNIa+BAO data, because of a dominant tension appearing in the $H_0 \,$-$\, \Omega_M$ 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 $\sum m_\nu \, / \, 3$ 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 $2 \sigma$ level, best-fitting at $\sum m_\nu \approx 0.21 {\, \rm eV}$, and the Bayesian tension disappears rendering the nonlocal gravity model statistically equivalent to $\Lambda$CDM, given recent CMB+SNIa+BAO data. We also discuss constraints from growth rate measurements $f \sigma_8$ whose fit is found to be improved by a larger massive neutrino fraction as well. The $\nu$-extended nonlocal model also prefers a higher value of $H_0$ than $\Lambda$CDM, therefore in better agreement with local measurements.

## Full text

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## Figures

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## References

117 references — full list in the complete paper: https://tomesphere.com/paper/1704.04075/full.md

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Source: https://tomesphere.com/paper/1704.04075