Abstract
It was recently pointed out that very energetic subclasses of supernovae (SNe), like hypernovae and superluminous SNe, might host ultrastrong magnetic fields in their core. Such fields may catalyze the production of feebly interacting particles, changing the predicted emission rates. Here we consider the case of axionlike particles (ALPs) and show that the predicted large scale magnetic fields in the core contribute significantly to the ALP production, via a coherent conversion of thermal photons. Using recent state-of-the-art supernova (SN) simulations, including magnetohydrodynamics, we find that, if ALPs have masses m_{a}∼O(10) MeV, their emissivity in such rare but exciting conditions via magnetic conversions would be over 2 orders of magnitude larger than previously estimated. Moreover, the radiative decay of these massive ALPs would lead to a peculiar delay in the arrival times of the daughter photons. Therefore, high-statistics gamma-ray satellites can potentially discover MeV ALPs in an unprobed region of the parameter space and shed light on the magnetohydrodynamical nature of the SN explosion.
Highlights
Andrea Caputo,1,2,3 Pierluca Carenza,4,5 Giuseppe Lucente,4,5 Edoardo Vitagliano,6 Maurizio Giannotti,7 Kei Kotake,8 Takami Kuroda,9 and Alessandro Mirizzi 4,5
We consider the case of axionlike particles (ALPs) and show that the predicted large scale magnetic fields in the core contribute significantly to the ALP production, via a coherent conversion of thermal photons
Using recent state-ofthe-art supernova (SN) simulations, including magnetohydrodynamics, we find that, if ALPs have masses ma ∼ Oð10Þ MeV, their emissivity in such rare but exciting conditions via magnetic conversions would be over 2 orders of magnitude larger than previously estimated
Summary
Andrea Caputo ,1,2,3 Pierluca Carenza ,4,5 Giuseppe Lucente ,4,5 Edoardo Vitagliano ,6 Maurizio Giannotti ,7 Kei Kotake, Takami Kuroda ,9 and Alessandro Mirizzi 4,5. It was recently pointed out that very energetic subclasses of supernovae (SNe), like hypernovae and superluminous SNe, might host ultrastrong magnetic fields in their core. Such fields may catalyze the production of feebly interacting particles, changing the predicted emission rates. The most plausible scenario to account for these extreme events requires additional energy injection via the magnetohydrodynamically driven (MHD) explosions [12] This situation has been explored in very recent dedicated numerical studies [13,14], finding that in this case the SN core might host ultrastrong magnetic fields (B ≳ 1015 G [15]). Such strong magnetic fields are a plausible origin for more common types
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