http://arxiv.org/abs/2204.09402
We infer the expected detection number of pair instability supernovae (PISNe) during the operation of the Euclid space telescope, based on two binary population models that are consistent with binary black holes (BHs) observed by gravitational waves. The two models consider different PISN criteria depending on the $^{12}$C$(\alpha, \gamma)^{16}$O reaction rate. The fiducial and $3\sigma$ models adopt the standard and $3\sigma$-smaller $^{12}$C$(\alpha, \gamma)^{16}$O reaction rate, which predicts that stars with helium core masses $65-135 M_\odot$ and $90-180 M_\odot$ cause PISNe, respectively. Our fiducial model predicts that Euclid detects several Type I or hydrogen-poor PISNe. For the $3\sigma$ model, detection of $\sim 1$ Type I PISN by Euclid is expected if the stellar mass distribution extends to $M_{\max} \sim 600 M_\odot$, but the expected number becomes significantly smaller if $M_{\max} \sim 300 M_\odot$. Thus, we may be able to prove or distinguish the fiducial and $3\sigma$ models by the observed PISN rate. This will help us to constrain the origin of binary BHs and the $^{12}$C$(\alpha, \gamma)^{16}$O reaction rate. PISN ejecta mass estimates from light curves and spectra obtained by follow-up observations would also be important to constrain the $^{12}$C$(\alpha, \gamma)^{16}$O reaction rate.
A. Tanikawa, T. Moriya, N. Tominaga, et. al.
Thu, 21 Apr 22
67/73
Comments: 4 pages, 4 figures, submitted
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