A Systematic Study of Magnetic Fields Impacts on Neutrino Transport in Core-Collapse Supernovae

Abstract

We quantify the impact of strong magnetic fields (assuming B=B0· r03/r3 with B0 1016 G) on the neutrino transport in core-collapse supernovae (CCSNe). Magnetic fields quantize the momenta of electrons and positrons, resulting in an enhanced absorption cross section for low-energy neutrinos and suppressed chemical potentials for e. We include these changes in the M1 scheme for neutrino transport and perform 1-D CCSNe simulations with GR1D. The increased low-energy cross sections reduce the e mean energy E_e while elevating the neutrino number luminosities L for both e and e due to the lower energy weighted spectra. The reduction of chemical potential enhances the e emission while suppressing that of e, thereby driving an increase in the electron fraction behind the stalled shock at 30--100 km. This further amplifies E_e through an increased electron density. Consequently, magnetic fields amplify L_e by increasing both L_e and E_e whereas for e, the rise in L_e is offset by a decreased E_e, leading to a minimal change in L_e. A systematic parameter scan of dipole field configurations suggests that, for r0 > 30 km, E_e is significantly suppressed and L_e is enhanced if B0 ≥ 2.7 × 1016 G. These magnetic effects become negligible for B0 below 7.4 × 1015 G.

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