Neutrinos interact only weakly with ordinary matter. Yet in certain astrophysical contexts, such as supernova explosions, the coupled interactions between neutrinos and dense, highly ionized plasmas contribute significantly to a system’s evolution. Modeling such systems is complicated enough even in the absence of neutrinos, and it normally requires analytic approximations or detailed numerical simulations. Adding neutrino effects entails further compromises; past approaches, for example, typically consider energy exchange between neutrinos and a neutral fluid. Now Fernando Haas and Kellen Alves Pascoal (Federal University of Rio Grande do Sul, Brazil) and Tito Mendonça (University of Lisbon, Portugal) propose a new framework for integrating relevant aspects of neutrino and plasma physics. Their approach, which they dub neutrino magnetohydrodynamics (NMHD), systematically extends MHD, which treats a plasma’s electrons and ions as fluids and considers the dynamics of the magnetic field they produce, to include the weak interaction, which in particle physics describes the...

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