Neutrino mass bounds from DESI 2024 are relaxed by Planck PR4 and cosmological supernovae

TL;DR

This paper shows that combining DESI 2024 BAO data with Planck PR4 and supernovae datasets relaxes neutrino mass bounds, making both hierarchies compatible and addressing tensions in cosmological measurements.

Contribution

It demonstrates that neutrino mass bounds are significantly less restrictive when including Planck PR4 and supernovae data, resolving previous tensions and allowing both hierarchies.

Findings

Neutrino mass bounds are relaxed to <0.1 eV with new datasets.

Both normal and inverted hierarchies remain viable.

Extended models with Dark Radiation further relax bounds.

Abstract

The recent DESI 2024 Baryon Acoustic Oscillations (BAO) measurements combined with the CMB data from the Planck 18 PR3 dataset and the Planck PR4+ACT DR6 lensing data, with a prior on the sum of the neutrino masses $\sum m_\nu>0$, leads to a strong constraint, $\sum m_\nu<0.072$ eV, which would exclude the inverted neutrino hierarchy and put some tension on even the standard hierarchy. We show that actually this bound gets significantly relaxed when combining the new DESI measurements with the HiLLiPoP+LoLLiPoP likelihoods, based on the Planck 2020 PR4 dataset, and with supernovae datasets. We note that the fact that neutrino masses are pushed towards zero, and even towards negative values, is known to be correlated with the so-called $A_L$ tension, a mismatch between lensing and power spectrum measurements in the Planck PR3 data, which is reduced by HiLLiPoP+LoLLiPoP to less than 1$\sigma$. We find $\sum m_\nu<0.1$ eV and $\sum m_\nu<0.12$ eV, with the supernovae Pantheon+ and DES-SN5YR datasets respectively. The shift caused by these datasets is more compatible with the expectations from neutrino oscillation experiments, and both the normal and inverted hierarchy scenarios remain now viable, even with the $\sum m_\nu>0$ prior. Finally, we analyze neutrino mass bounds in an extension of $\Lambda$CDM that addresses the $H_0$ tension, with extra fluid Dark Radiation, finding that in such models bounds are further relaxed and the posterior probability for $\sum m_\nu$ begins to exhibit a peak at positive values.