Examination of the role of the $^{14}$O($\alpha$,$p$)$^{17}$F reaction rate in type I x-ray bursts

TL;DR

This study investigates the $^{14}$O($$,$p$)$^{17}$F reaction rate's role in type I x-ray bursts by experimental resonance measurements and analyzes its impact on astrophysical models, revealing only modest effects despite rate uncertainties.

Contribution

The paper provides new experimental data on resonances in $^{18}$Ne and derives an updated thermonuclear reaction rate for $^{14}$O($$,$p$)$^{17}$F, with implications for x-ray burst modeling.

Findings

Identification of five resonances in $^{18}$Ne

Firm assignment of $J^{\u00b1}}$=1$^-$ to the 6.15 MeV state

Modest impact of reaction rate variations on XRB energy generation

Abstract

The $^{14}$O($\alpha$,$p$)$^{17}$F reaction is one of the key reactions involved in the breakout from the hot-CNO cycle to the rp-process in type I x-ray bursts (XRBs). The resonant properties in the compound nucleus $^{18}$Ne have been investigated through resonant elastic scattering of $^{17}$F+$p$. The radioactive $^{17}$F beam was separated by the CNS Radioactive Ion Beam separator (CRIB) and bombarded a thick H$_2$ gas target at 3.6 MeV/nucleon. The recoiling light particles were measured by three ${\Delta}$E-E silicon telescopes at laboratory angles of $\theta$$_{lab}$$\approx$3$^\circ$, 10$^\circ$ and 18$^\circ$, respectively. Five resonances at $E_{x}$=6.15, 6.28, 6.35, 6.85, and 7.05 MeV were observed in the excitation functions, and their spin-parities have been determined based on an $R$-matrix analysis. In particular, $J^{\pi}$=1$^-$ was firmly assigned to the 6.15-MeV state which dominates the thermonuclear $^{14}$O($\alpha$,$p$)$^{17}$F rate below 2 GK. As well, a possible new excited state in $^{18}$Ne was observed at $E_{x}$=6.85$\pm$0.11 MeV with tentative $J$=0 assignment. This state could be the analog state of the 6.880 MeV (0$^{-}$) level in the mirror nucleus $^{18}$O, or a bandhead state (0$^+$) of the six-particle four-hole (6$p$-4$h$) band. A new thermonuclear $^{14}$O($\alpha$,$p$)$^{17}$F rate has been determined, and the astrophysical impact of multiple recent rates has been examined using an XRB model. Contrary to previous expectations, we find only modest impact on predicted nuclear energy generation rates from using reaction rates differing by up to several orders of magnitude.