Gregory S. Vance, Patrick A. Young, Christopher L. Fryer, Carola I. Ellinger
Published 2020-05-07Version 1
Mixing above the proto-neutron star is believed to play an important role in the supernova engine, and this mixing results in a supernova explosion with asymmetries. Elements produced in the innermost ejecta, e.g., ${}^{56}$Ni and ${}^{44}$Ti, provide a clean probe of this engine. The production of ${}^{44}$Ti is particularly sensitive to the exact production pathway and, by understanding the available pathways, we can use ${}^{44}$Ti to probe the supernova engine. Using thermodynamic trajectories from a three-dimensional supernova explosion model, we review the production of these elements and the structures expected to form under the "convective-engine" paradigm behind supernovae. We compare our results to recent X-ray and $\gamma$-ray observations of the Cassiopeia A supernova remnant.
Comments: v1: 14 pages of text, 24 figures, 2 tables; to be published in ApJ
A Neutron Star with a Carbon Atmosphere in the Cassiopeia A Supernova Remnant
XMM-Newton detection of the supernova remnant G304.6+0.1 (Kes 17)
X-ray spectroscopy of the candidate AGN in Henize 2-10 and NGC 4178: Likely supernova remnants
![QR code for arXiv:2005.03777 [astro-ph.HE]](http://oss.arxitics.com/images/favicon.svg)