Dark matter sterile neutrinos in stellar collapse: alteration of energy/lepton number transport and a mechanism for supernova explosion enhancement
Abstract
We investigate matter-enhanced Mikheyev-Smirnov-Wolfenstein (MSW) active-sterile neutrino conversion in the e s channel in the collapse of the iron core of a pre-supernova star. For values of sterile neutrino rest mass ms and vacuum mixing angle θ (specifically, 0.5 keV< ms<10 keV and 22θ> 5×10-12) which include those required for viable sterile neutrino dark matter, our one-zone in-fall phase collapse calculations show a significant reduction in core lepton fraction. This would result in a smaller homologous core and therefore a smaller initial shock energy, disfavoring successful shock re-heating and the prospects for an explosion. However, these calculations also suggest that the MSW resonance energy can exhibit a minimum located between the center and surface of the core. In turn, this suggests a post-core-bounce mechanism to enhance neutrino transport and neutrino luminosities at the core surface and thereby augment shock re-heating: (1) scattering-induced or coherent MSW es conversion occurs deep in the core, at the first MSW resonance, where e energies are large ( 150 MeV); (2) the high energy s stream outward at near light speed; (3) they deposit their energy when they encounter the second MSW resonance se just below the proto-neutron star surface.
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