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

Allali, Itamar J.; Notari, Alessio

doi:10.1088/1475-7516/2024/12/020

J. Cosmol. Astropart. Phys.

2024

DOI: 10.1088/1475-7516/2024/12/020

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

Itamar J. Allali,

Alessio Notari

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 ∑ m ν > 0, leads to a strong constraint, ∑ m ν < 0.072 eV, which would exclude the inverted neutrino hierarchy and put some tension on even the standard hierarchy. We show th… Show more

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Massive neutrinos and cosmic composition

Loverde,

Weiner

2024

J. Cosmol. Astropart. Phys.

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Cosmological data probe massive neutrinos via their effects on the geometry of the Universe and the growth of structure, both of which are degenerate with the late-time expansion history. We clarify the nature of these degeneracies and the individual roles of both probes in neutrino mass inference. Geometry is strongly sensitive to neutrino masses: within ΛCDM, the primary cosmic microwave background anisotropies alone impose that the matter fraction Ω m must increase fivefold with increasing neutrino mass. Moreover, large-scale structure observables, like weak lensing of the CMB, are dimensionless and thus depend not on the matter density (as often quoted) but in fact the matter fraction. We explore the consequential impact of this distinction on the interplay between probes of structure, low-redshift distances, and CMB anisotropies. We derive constraints on the neutrino's masses independently from their suppression of structure and impact on geometry, showing that the latter is at least as important as the former. While the Dark Energy Spectroscopic Instrument's recent baryon acoustic oscillation data place stringent bounds largely deriving from their geometric incompatibility with massive neutrinos, all recent type Ia supernova datasets drive marginal preferences for nonzero neutrino masses because they prefer substantially larger matter fractions. Recent CMB lensing data, however, neither exclude neutrinos' suppression of structure nor constrain it strongly enough to discriminate between mass hierarchies. Current data thus evince not a need for modified dynamics of neutrino perturbations or structure growth but rather an inconsistent compatibility with massive neutrinos' impact on the expansion history. We identify two of DESI's measurements that strongly influence its constraints, and we also discuss neutrino mass measurements in models that alter the sound horizon.

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Massive neutrinos and cosmic composition

Loverde,

Weiner

2024

J. Cosmol. Astropart. Phys.

View full text Add to dashboard Cite

show abstract

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

Cited by 1 publication

References 34 publications

Massive neutrinos and cosmic composition

Massive neutrinos and cosmic composition

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