Abstract
Neutrino flavor instabilities have the potential to shuffle neutrinos between electron, mu, and tau flavor states, possibly modifying the core-collapse supernova mechanism and the heavy elements ejected from neutron star mergers. Analytic methods indicate the presence of so-called fast flavor transformation instabilities, and numerical simulations can be used to probe the nonlinear evolution of the neutrinos. Simulations of the fast flavor instability to date have been performed assuming imposed symmetries. We perform simulations of the fast flavor instability that include all three spatial dimensions and all relevant momentum dimensions in order to probe the validity of these approximations. If the fastest growing mode has a wave number along a direction of imposed symmetry, then the instability can be suppressed. The late-time equilibrium distribution of flavor, however, seems to be little affected by the number of spatial dimensions. This is a promising hint that the results of lower-dimensionality simulations to date have predictions that are robust against their the number of spatial dimensions, though simulations of a wider variety of neutrino distributions need to be carried out to support this claim more generally.
Highlights
Neutrinos are produced in immense numbers in corecollapse supernovae and neutron star mergers, but the neutrino’s elusive nature and behavior currently limits our understanding of these explosive astrophysical phenomena
We focus on three different physical conditions to elucidate the role of symmetries in the outcome of the fast flavor instability
We perform the first simulations of the fast flavor instability in three spatial dimensions and two momentum dimensions
Summary
Neutrinos are produced in immense numbers in corecollapse supernovae and neutron star mergers, but the neutrino’s elusive nature and behavior currently limits our understanding of these explosive astrophysical phenomena. When two neutron stars or a neutron star and a black hole merge, the neutrinos emitted from the resulting hot accretion disk can enhance outflows that form heavy elements (see [3] for a recent review). In both cases, the matter ejected pollutes the surrounding environment with metals that later form more metal-rich stars, planets, and life.
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