http://arxiv.org/abs/2111.01151
Core-collapse supernovae (CCSNe) produce large ($\gtrsim 0.1 \, {\rm M}\odot$) masses of dust, and are potentially the primary source of dust in the Universe, but much of this dust may be destroyed before reaching the interstellar medium. Cassiopeia A (Cas A) is the only supernova remnant where an observational measurement of the dust destruction efficiency in the reverse shock is possible at present. We determine the pre- and post-shock dust masses in Cas A using a substantially improved dust emission model. In our preferred models, the unshocked ejecta contains $0.6-0.8 \, {\rm M}\odot$ of $0.1 \, {\rm \mu m}$ silicate grains, while the post-shock ejecta has $0.02-0.09 \, {\rm M}\odot$ of $5-10 {\, {\rm nm}}$ grains in dense clumps, and $2 \times 10^{-3} \, {\rm M}\odot$ of $0.1 \, {\rm \mu m}$ grains in the diffuse X-ray emitting shocked ejecta. The implied dust destruction efficiency is $74-94 \%$ in the clumps and $92-98 \%$ overall, giving Cas A a final dust yield of $0.05-0.30 \, {\rm M}\odot$. If the unshocked ejecta grains are larger than $0.1 \, {\rm \mu m}$, the dust masses are higher, the destruction efficiencies are lower, and the final yield may exceed $0.5 \, {\rm M}\odot$. As Cas A has a dense circumstellar environment and thus a much stronger reverse shock than is typical, the average dust destruction efficiency across all CCSNe is likely to be lower, and the average dust yield higher. This supports a mostly-stellar origin for the cosmic dust budget.
F. Priestley, M. Arias, M. Barlow, et. al.
Wed, 3 Nov 21
47/106
Comments: 10 pages, 9 figures, MNRAS accepted