http://arxiv.org/abs/1501.07283
The death of massive stars is believed to involve aspheric explosions initiated by the collapse of an iron core. The specifics of how these catastrophic explosions proceed remain uncertain due, in part, to limited observational constraints on various processes that can introduce asymmetries deep inside the star. Here we present near-infrared observations of the young Milky Way supernova remnant Cassiopeia A, descendant of a type IIb core-collapse explosion, and a three-dimensional map of its interior, unshocked ejecta. The remnant’s interior has a bubble-like morphology that smoothly connects to and helps explain the multi-ringed structures seen in the remnant’s bright reverse shocked main shell of expanding debris. This internal structure may have originated from turbulent mixing processes that encouraged the development of outwardly expanding plumes of radioactive 56Ni-rich ejecta. If this is true, substantial amounts of its decay product, 56Fe, may still reside in these interior cavities.
D. Milisavljevic and R. Fesen
Fri, 30 Jan 15
16/47
Comments: 22 pages, 4 figures, including online supporting material; published in Science on 30 January 2015; interactive web app available at this https URL
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