A systematic study of magnetar-powered hydrogen-rich supernovae

TL;DR

This study investigates how magnetars influence the light curves of hydrogen-rich supernovae, revealing diverse possible brightness evolutions and suggesting magnetar-powered supernovae could explain various observed phenomena.

Contribution

It introduces a novel modeling approach for magnetar-powered hydrogen-rich supernovae, expanding understanding of their light curve diversity and potential observational signatures.

Findings

Magnetars can produce plateau phases in supernova light curves.

Bright, long-rising supernovae are possible with RSG progenitors.

Various light curve morphologies indicate magnetar influence in hydrogen-rich supernovae.

Abstract

Context: It has been suggested that some supernovae (SNe) may be powered by a magnetar formed at the moment of the explosion. While this scenario has mostly been applied to hydrogen-free events, it may be possible also for hydrogen-rich objects. Aims: We explore the effect of including a magnetar on the light curves of supernovae with H-rich progenitors. Methods: We have applied a version of our one-dimensional LTE radiation hydrodynamics code that takes into account the relativistic motion of the ejecta caused by the extra energy provided by the magnetar. For a fixed red supergiant (RSG) progenitor, we have obtained a set of light curves that corresponds to different values of the magnetar initial rotation energy and the spin-down timescale. The model is applied to SN~2004em and OGLE-2014-SN-073, two peculiar Type II SNe with long-rising SN1987A-like light curves, although with much larger luminosities. Results: The presence of a plateau phase in either normal or superluminous supernovae is one possible outcome, even if a magnetar is continuously injecting energy into the ejecta.In other cases, the light curve shows a peak but not a plateau. Also, there are intermediate events with a first peak followed by a slow decline and a late break of the declining slope. Our models show that bright and long rising morphologies are possible even assuming RSG structures. Conclusions: A large number of supernova discoveries per year reveal unexpected new types of explosions. According to our results, SLSNe II-P are to be expected, as well as a variety of light curve morphologies that can all be possible signs of a newly born magnetar.