New limits on neutrino decay from the Glashow resonance of high-energy cosmic neutrinos

Abstract

Discovering neutrino decay would be strong evidence of physics beyond the Standard Model. Presently, there are only lax lower limits on the lifetime τ of neutrinos, of τ/m 10-3 s eV-1 or worse, where m is the unknown neutrino mass. High-energy cosmic neutrinos, with TeV-PeV energies, offer superior sensitivity to decay due to their cosmological-scale baselines. To tap into it, we employ a promising method, recently proposed, that uses the Glashow resonance e + e W, triggered by e of 6.3 PeV, to test decay with only a handful of detected events. If most of the 1 and 2 decay into 3 en route to Earth, no Glashow resonance would occur in neutrino telescopes, because the remaining 3 have only a tiny electron-flavor content. We turn this around and use the recent first detection of a Glashow resonance candidate in IceCube to place new lower limits on the lifetimes of 1 and 2. For 2, our limit is the current best. For 1, our limit is close to the current best and, with the imminent detection of a second Glashow resonance, will vastly surpass it.