Abstract
Background: The recent observation of a neutron-star merger finally confirmed one astrophysical location of the rapid neutron-capture process (r-process). Evidence of the production of A < 140 nuclei was seen, but there is still little detailed information about how those lighter elements are produced in such an environment. Many of the questions surrounding the A ≈ 80 nuclei are likely to be answered only when the nuclear physics involved in the production of r-process nuclei is well understood. Neutron-capture reactions are an important component of the r-process, and neutron-capture cross sections of r-process nuclei, which are very neutron rich, have large uncertainties.
Purpose: Indirectly determine the neutron-capture cross section and reaction rate of 73Zn(n, γ ) 74Zn.
Methods: The nuclear level density (NLD) and γ -ray strength function (γ SF) of 74Zn were determined following a total absorption spectroscopy (TAS) experiment focused on the β decay of 74Cu into 74Zn performed at the National Superconducting Cyclotron Laboratory. The NLD and γ SF were used as inputs in a Hauser-Feshbach statistical model to calculate the neutron-capture cross section and reaction rate.
Results: The NLD and γ SF of 74Zn were experimentally constrained for the first time using β-delayed γ rays measured with TAS and the β-Oslo method. The NLD and γ SF were then used to constrain the neutron-capture cross section and reaction rate for the 73Zn(n, γ ) 74Zn reaction.
Conclusions: The uncertainty in the neutron-capture cross section and reaction rate of 73Zn(n, γ ) 74Zn calculated in TALYS was reduced to under a factor of 2 from a factor of 5 in the cross section and a factor of 11 in the reaction rate using the experimentally obtained NLD and γ SF.