Production of heavy α-elements and 44Ti in Cas A: comparison to abundances from 1D core-collapse supernova models and evidence for Carbon-Oxygen shell mergers
Abstract
The merger between the carbon (C) and oxygen (O) shells hours to days before the collapse of a massive star significantly changes its nucleosynthesis, which is reflected in the elemental ratios observed in supernova remnants (SNRs). We present a nucleosynthesis study of 44Ti production in core-collapse supernovae (CCSNe), highlighting large silicon (Si), sulfur (S), calcium (Ca), and, most importantly, argon (Ar) to neon (Ne) ratios as diagnostics for carbon-oxygen (C--O) shell mergers. We compare yields from eight different sets of CCSNe models to observations of Cassiopeia A (Cas A), and show that C--O shell mergers are consistently the models that best match X-ray and infrared observations. These models produce high Ar/Ne ratios ( 0.1), due to 20Ne depletion and production of 36Ar and 38Ar, while lower ratios are obtained from non-merger cases. Based on the Ar/Ne diagnostic, we compare the range of expected 44Ti produced by C--O shell mergers, which is up to 20 - 30 \% of the overall 44Ti, but expected to be located outside the reverse shock. Based on the sets of models considered, the photon flux expected from the 44Ti synthesized in the C--O shell merger in Cas A is below the NuSTAR and COSI detection limits, compatible with current limits locating most of the 44Ti interior to the reverse shock, but might be detectable from proposed missions like ASCENT. Finally, for the SNR of 1987A, a dominant C--O merger origin of the observed 44Ti is unlikely based on the observed redshift in its 44Ti line.
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