Magnetic support for neutrino-driven explosion of 3D non-rotating core-collapse supernova models

The impact of the magnetic field on post-bounce supernova dynamics of non-rotating stellar cores is studied by performing 3D magnetohydrodynamics simulations with spectral neutrino transport. The explodability of strongly and weakly magnetized models of 20 and 27 M-circle dot pre-supernova progenitors are compared. We find that although the efficiency for the conversion of the neutrino heating into turbulent energy including magnetic fields in the gain region is not significantly different between the strong and weak field models, the amplified magnetic field due to the neutrino-driven convection on large hot bubbles just behind stalled shock results in a faster and more energetic explosion in the strongly magnetized models. In addition, by comparing the difference between the 2nd- and 5th-order spatial accuracy of the simulation in the strong field model for 27 M-circle dot progenitor, we also find that the higher order accuracy in space is beneficial to the explosion because it enhances the growth of neutrino-driven convection in the gain region. Based on our results of core-collapse supernova simulations for the non-rotating model, a new possibility for the origin of the magnetic field of the protoneutron star (PNS) is proposed. The magnetic field is accumulated and amplified to magnetar level, that is, O(10(14))G, in the convectively stable shell near the PNS surface.

Automated summary

The impact of magnetic field on post-bounce supernova dynamics of non-rotating stellar cores is investigated through 3D magnetohydrodynamics simulations. It is found that the amplified magnetic field in strongly magnetized models leads to a faster and more energetic explosion. Additionally, higher order spatial accuracy enhances neutrino-driven convection and benefits the explosion. A new possibility for the origin of the magnetic field of the protoneutron star is proposed.