Abstract
We present a detailed report of the connection between long-duration gamma-ray bursts (GRBs) and their accompanying supernovae (SNe). The discussion presented here places emphasis on how observations, and the modelling of observations, have constrained what we know about GRB-SNe. We discuss their photometric and spectroscopic properties, their role as cosmological probes, including their measured luminosity–decline relationships, and how they can be used to measure the Hubble constant. We present a statistical summary of their bolometric properties and use this to determine the properties of the “average” GRB-SN. We discuss their geometry and consider the various physical processes that are thought to power the luminosity of GRB-SNe and whether differences exist between GRB-SNe and the SNe associated with ultra-long-duration GRBs. We discuss how observations of their environments further constrain the physical properties of their progenitor stars and give a brief overview of the current theoretical paradigms of their central engines. We then present an overview of the radioactively powered transients that have been photometrically associated with short-duration GRBs, and we conclude by discussing what additional research is needed to further our understanding of GRB-SNe, in particular the role of binary-formation channels and the connection of GRB-SNe with superluminous SNe.
Highlights
Observations have proved the massive-star origins of longduration gamma-ray bursts (GRBs) (LGRBs) beyond any reasonable doubt
We present a statistical summary of their bolometric properties and use this to determine the properties of the “average” gamma-ray burst supernova (GRB-SN)
We discuss their geometry and consider the various physical processes that are thought to power the luminosity of GRB-SNe and whether differences exist between GRB-SNe and the SNe associated with ultra-long-duration GRBs
Summary
Observations have proved the massive-star origins of longduration GRBs (LGRBs) beyond any reasonable doubt. It was shown that SN 1998bw had a very large kinetic energy (see Section 4 and Table 3) of ∼2–5 × 1052 erg, which led it to being referred to as a hypernova [3]. Given several peculiarities of its γray properties, including its underluminous γ-ray luminosity (L훾,iso ∼ 5 × 1046 erg s−1), it was doubted whether this event was truly representative of the general LGRB population. This uncertainty persisted for almost five years until the spectroscopic association between cosmological/high-luminosity GRB 030329 (L훾,iso ∼ 8 × 1050 erg s−1) and SN 2003dh [4,5,6].
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