Updated Bounds on Sum of Neutrino Masses in Various Cosmological Scenarios

Abstract

We present strong bounds on the sum of three active neutrino masses (Σ m) in various cosmological models. We use the following baseline datasets: CMB temperature data from Planck 2015, BAO measurements from SDSS-III BOSS DR12, the newly released SNe Ia dataset from Pantheon Sample, and a prior on the optical depth to reionization from 2016 Planck Intermediate results. We constrain cosmological parameters in CDM model with 3 massive active neutrinos. For this CDM+Σ m model we find a upper bound of Σ m < 0.152 eV at 95\% C.L. Adding the high-l polarization data from Planck strengthens this bound to Σ m < 0.118 eV, which is very close to the minimum required mass of Σ m 0.1 eV for inverted hierarchy. This bound is reduced to Σ m < 0.110 eV when we also vary r, the tensor to scalar ratio ( CDM+r+Σ m model), and add an additional dataset, BK14, the latest data released from the Bicep-Keck collaboration. This bound is further reduced to Σ m < 0.101 eV in a cosmology with non-phantom dynamical dark energy (w0 wa CDM+Σ m model with w(z)≥ -1 for all z). Considering the w0 wa CDM+r+Σ m model and adding the BK14 data again, the bound can be even further reduced to Σ m < 0.093 eV. For the w0 wa CDM+Σ m model without any constraint on w(z), the bounds however relax to Σ m < 0.276 eV. Adding a prior on the Hubble constant (H0 = 73.24 1.74 km/sec/Mpc) from Hubble Space Telescope (HST), the above mentioned bounds further improve to Σ m < 0.117 eV, 0.091 eV, 0.085 eV, 0.082 eV, 0.078 eV and 0.247 eV respectively. This substantial improvement is mostly driven by a more than 3σ tension between Planck 2015 and HST measurements of H0 and should be taken cautiously. (abstract abridged)