New Gauge Forces, Neutron Stars and Schwinger Neutrino Production

Abstract

We investigate neutrino effects of new long-range forces arising from gauging B-L, Le-Lμ/τ or Lμ-Lτ symmetries of the Standard Model. The leptonic potential generated by astronomical bodies, such as the Earth, the Sun or a neutron star, results in the Schwinger pair production of neutrinos charged under the new gauge symmetry. The oppositely charged particles accumulate in the potential well forming a degenerate Fermi gas, while equally charged particles fly away forming a steady flux of neutrinos. We find that, for the B-L and Le-Lμ/τ forces, these effects are too weak to be observable. For the Lμ-Lτ force these effects are significant in neutron stars if the gauge coupling is g 10-18. The muonic force changes the element abundances of a neutron star in equilibrium and suppresses its Lμ-Lτ charge. This invalidates the constraint on g from neutron star mergers, at g 10-17. Furthermore, for such values of g, the neutrino flux produced by the Schwinger effect could potentially be detected from a single young neutron star at a distance of 100 pc, with the typical neutrino energy Eν 100 MeV. A dedicated search for such a signal will reassert the bound g 10-18.