Probing the neutrino chemical potential with cosmological observations

Abstract

The electron neutrino degeneracy parameter, ξνe = μνe / T, is tightly constrained by Big Bang Nucleosynthesis (BBN), while the degeneracy parameters of the other neutrino species, ξνx, remain weakly constrained by cosmological observations alone. In this manuscript we shall compute up-to-date bounds on ξνe and ξνx assuming that either they are constant free-parameters along the cosmic history or that they are redshift dependent quantities. In the latter case we employ a model-independent reconstruction approach based on the Piecewise Cubic Hermite Interpolating Polynomial (PCHIP) formalism with four nodes, located at z 10, 100, 1000 and 108. We shall also consider two scenarios for neutrinos, specifically three degenerate neutrinos (ξνe = ξνx) and the case in which we actually differentiate between ξνe and ξνx. We perform a cosmological analysis combining CMB data from Planck, SPT, and ACT with BAO measurements from DESI, showing the impact of including BBN observables from either EMPRESS results, which allow for a non-zero chemical potential, or from LBT observations, compatible with the standard ξν = 0 prediction. We explicitly show that the BBN data, via the change in neutron-to-proton interconversion rates, mostly constrain ξνe, parameter for which we observe a preferred non-zero positive value at 95\% C.L. in the non-degenerate neutrino case at the BBN period. Since the Hubble constant is correlated with ξν, through N eff, a larger value of H0 is allowed within these models, making them really interesting scenarios where to test non-standard physics models.