http://arxiv.org/abs/1401.3032
Although the details of the core-collapse supernova mechanism are not fully understood, it is generally accepted that the energy released in the collapse produces a shock that disrupts the star and produces the explosion. Some of the stellar material does not receive enough energy to escape the potential well of the newly formed neutron star and it falls back on to the core. This fallback plays an important role in setting compact remnant masses and has been invoked to explain a number of observed phenomena: late-time neutrino emission, r-process element production, peculiar supernovae, and long-duration gamma-ray bursts. To examine the link between fallback and these observed phenomena, we must understand the nature of fallback and currently, multiple mechanisms have been proposed that lead to different characteristics of the fallback. In this paper, we model a series of three-dimensional explosions by following the fallback for two different massive progenitors to study both the nature of the fallback and the role of asymmetric explosions on this fallback. One of the most-cited mechanisms behind fallback argues that it is caused by the reverse shock produced when the outward moving supernova shock decelerates in the relatively flat density profile of the stellar envelope. We show that this mechanism plays a minor, if any, role in driving fallback and most supernova fallback is produced by prompt mechanisms.
Wed, 15 Jan 14
57/67
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