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Production of <sup>44</sup>Ti and Iron-group Nuclei in the Ejecta of 3D Neutrino-driven Supernovae

André Sieverding, Daniel Kresse, Hans‐Thomas Janka

2023The Astrophysical Journal Letters31 citationsDOIOpen Access PDF

Abstract

Abstract The radioactive isotopes 44 Ti and 56 Ni are important products of explosive nucleosynthesis, which play a key role in supernova (SN) diagnostics and have been detected in several nearby young SN remnants. However, most SN models based on nonrotating single stars predict yields of 44 Ti that are much lower than the values inferred from observations. We present, for the first time, the nucleosynthesis yields from a self-consistent three-dimensional SN simulation of a ∼19 M ⊙ progenitor star that reaches an explosion energy comparable to that of SN 1987A and that covers the evolution of the neutrino-driven explosion until more than 7 s after core bounce. We find a significant enhancement of the Ti/Fe yield compared to recent spherically symmetric (1D) models and demonstrate that the long-time evolution is crucial to understanding the efficient production of 44 Ti due to the nonmonotonic temperature and density history of the ejected material. Additionally, we identify characteristic signatures of the nucleosynthesis in proton-rich ejecta, in particular high yields of 45 Sc and 64 Zn.

Topics & Concepts

NucleosynthesisEjectaSupernovaPhysicsNeutrinoIron groupAstrophysicsExplosive materialStarsYield (engineering)ProtonIsotopeNuclear physicsChemistryOrganic chemistryMetalThermodynamicsGamma-ray bursts and supernovaeNeutrino Physics ResearchNuclear physics research studies
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