Weaker yet again: mass spectrum-consistent cosmological constraints on the neutrino lifetime

Abstract

We consider invisible neutrino decay H l + φ in the ultra-relativistic limit and compute the neutrino anisotropy loss rate relevant for the cosmic microwave background (CMB) anisotropies. Improving on our previous work which assumed massless l and φ, we reinstate in this work the daughter neutrino mass m l in a manner consistent with the experimentally determined neutrino mass splittings. We find that a nonzero m l introduces a new phase space factor in the loss rate T proportional to ( m2/m_H2)2 in the limit of a small squared mass gap between the parent and daughter neutrinos, i.e., T ( m2/m H2)2 (m H/E )5 (1/τ0), where τ0 is the H rest-frame lifetime. Using a general form of this result, we update the limit on τ0 using the Planck 2018 CMB data. We find that for a parent neutrino of mass m H 0.1 eV, the new phase space factor weakens the constraint on its lifetime by up to a factor of 50 if m2 corresponds to the atmospheric mass gap and up to 105 if the solar mass gap, in comparison with naive estimates that assume m l=0. The revised constraints are (i) τ0 (6 10) × 105~ s and τ0 (400 500)~ s if only one neutrino decays to a daughter neutrino separated by, respectively, the atmospheric and the solar mass gap, and (ii) τ0 (2 3) × 107~ s in the case of two decay channels with one near-common atmospheric mass gap. In contrast to previous, naive limits which scale as m H5, these mass spectrum-consistent τ0 constraints are remarkably independent of the parent mass and open up a swath of parameter space within the projected reach of IceCube and other neutrino telescopes in the next two decades.