First Accurate Normalization of the $\beta$-delayed $\alpha$ Decay of   $^{16}$N and Implications for the $^{12}$C$(\alpha,\gamma)^{16}$O   Astrophysical Reaction Rate

O. S. Kirsebom; O. Tengblad; R. Lica; M. Munch; K. Riisager; H. O. U.; Fynbo; M. J. G. Borge; M. Madurga; I. Marroquin; A. N. Andreyev; T. A. Berry,; E. R. Christensen; P. D\'iaz Fern\'andez; D. T. Doherty; P. Van Duppen; L. M.; Fraile; M. C. Gallardo; P. T. Greenlees; L. J. Harkness-Brennan; N. Hubbard,; M. Huyse; J. H. Jensen; H. Johansson; B. Jonson; D. S. Judson; J. Konki; I.; Lazarus; M. V. Lund; N. Marginean; R. Marginean; A. Perea; C. Mihai; A.; Negret; R. D. Page; V. Pucknell; P. Rahkila; O. Sorlin; C. Sotty; J. A.; Swartz; H. B. S{\o}rensen; H. T\"ornqvist; V. Vedia; N. Warr; H. De Witte

arXiv:1804.02040·nucl-ex·October 10, 2018

First Accurate Normalization of the $\beta$-delayed $\alpha$ Decay of $^{16}$N and Implications for the $^{12}$C$(\alpha,\gamma)^{16}$O Astrophysical Reaction Rate

O. S. Kirsebom, O. Tengblad, R. Lica, M. Munch, K. Riisager, H. O. U., Fynbo, M. J. G. Borge, M. Madurga, I. Marroquin, A. N. Andreyev, T. A. Berry,, E. R. Christensen, P. D\'iaz Fern\'andez, D. T. Doherty, P. Van Duppen, L. M., Fraile, M. C. Gallardo, P. T. Greenlees

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TL;DR

This paper provides a more accurate measurement of the beta-delayed alpha decay of $^{16}$N, leading to improved constraints on the $^{12}$C$( ext{alpha}, ext{gamma})^{16}$O reaction rate crucial for astrophysics.

Contribution

The study offers the first precise normalization of the $^{16}$N beta-delayed alpha decay, resolving previous uncertainties and refining the $^{12}$C$( ext{alpha}, ext{gamma})^{16}$O reaction rate estimates.

Findings

01

Revised beta decay branching ratios for $^{16}$N.

02

Increased value of the reduced alpha width $oldsymbol{ ext{γ}}_{11}$.

03

Improved constraints on the astrophysical $^{12}$C$( ext{alpha}, ext{gamma})^{16}$O reaction rate.

Abstract

The $^{12} C (α, γ)^{16} O$ reaction plays a central role in astrophysics, but its cross section at energies relevant for astrophysical applications is only poorly constrained by laboratory data. The reduced $α$ width, $γ_{11}$ , of the bound $1^{-}$ level in $^{16}$ O is particularly important to determine the cross section. The magnitude of $γ_{11}$ is determined via sub-Coulomb $α$ -transfer reactions or the $β$ -delayed $α$ decay of $^{16}$ N, but the latter approach is presently hampered by the lack of sufficiently precise data on the $β$ -decay branching ratios. Here we report improved branching ratios for the bound $1^{-}$ level [ $b_{β, 11} = (5.02 \pm 0.10) \times 1 0^{- 2}$ ] and for $β$ -delayed $α$ emission [ $b_{β α} = (1.59 \pm 0.06) \times 1 0^{- 5}$ ]. Our value for $b_{β α}$ is 33% larger than previously held,…

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