Abstract
Reactions on certain proton-rich, radioactive nuclei have been shown to have a significant influence on X-ray bursts. We provide an overview of two recent measurements of important X-ray burst reactions using in-flight radioactive ion beams from the RESOLUT facility at the J. D. Fox Superconducting Accelerator Laboratory at Florida State University. The 17 F(d,n) 18 Ne reaction was measured, and Asymptotic Normalization Coefficients were extracted for bound states in 18 Ne that determine the direct-capture cross section dominating the 17 F(p, γ ) 18 Ne reaction rate for T≲ 0.45 GK. Unbound resonant states were also studied, and the single-particle strength for the 4.523-MeV (3 + ) state was found to be consistent with previous results. The 19 Ne(d,n) 20 Na proton transfer reaction was used to study resonances in the 19 Ne(p, γ ) 20 Na reaction. The most important 2.65-MeV state in 20 Na was observed to decay by proton emission to both the ground and first-excited states in 19 Ne, providing strong evidence for a 3 + spin assignment and indicating that proton capture on the thermally-populated first-excited state in 19 Ne is an important contributor to the 19 Ne(p, γ ) 20 Na reaction rate.
Highlights
X-ray bursts occur in binary systems when hydrogen-rich matter from a main-sequence star accretes onto a neutron star and ignites under degenerate conditions
The 600-keV resonance strength was directly measured at the Holifield Radioactive Ion Beam Facility [6], but the direct-capture contribution that dominates the reaction rate at T 0.45 GK remains uncertain
The 19Ne(p,γ)20Na reaction rate is dominated by contributions from resonances corresponding to states just above the proton-separation energy (S p = 2.19 MeV) in 20Na
Summary
X-ray bursts occur in binary systems when hydrogen-rich matter from a main-sequence star accretes onto a neutron star and ignites under degenerate conditions. The 17F(p,γ)18Ne reaction rate is determined mainly by contributions from direct capture and a single 3+ resonance at Ecm = 600 keV.
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