Electron Capture Strength for {60,62}Ni and {58,60,62,64}Ni(p,n){58,60,62,64}Cu reactions at 134.3 MeV

TL;DR

This study demonstrates that (p,n) reactions at 134.3 MeV can be used to determine electron capture strength in medium mass nuclei, providing insights relevant for supernova evolution and potential application to radioactive nuclei.

Contribution

It shows the feasibility of extracting electron capture strength from (p,n) reactions and explores the possibility of applying this method to radioactive nuclei in inverse kinematics.

Findings

Identified T_o+1 excitations in Ni isotopes and extracted B(GT) values.

Reanalyzed existing (n,p) data showing moderate agreement with (p,n) results.

Suggested future measurements with radioactive nuclei using inverse kinematics.

Abstract

Background: The strength of electron capture for medium mass nuclei has a significant effect on the evolution of supernovae. There is insufficient knowledge of these strengths and very little data for important radioactive nuclei. Purpose: Determine whether it is feasible to obtain EC strength from studies of T_o+1 excitations in (p,n) reactions, and whether this might yield information for radioactive nuclei. Methods: Cross sections for the {58,60,62,64}Ni(p,n){58,60,62,64}Cu reactions were measured over the angular range of 0.3 deg to 11.6 deg at 134.3 MeV using the IUCF neutron time-of-flight facility. esults: The T_o+1 excitations in {60,62}Ni were identified by comparison with inelastic proton scattering spectra, their B(GT) were extracted, and the corresponding electron capture rates in supernovae were calculated. Data from the TRIUMF (n,p) experiments at 198 MeV were reanalyzed; the electron capture rates for the reanalyzed data are in moderately good agreement with the higher resolution (p,n) results, but differ in detail. The possibility of future measurements with radioactive nuclei was considered. Conclusions: It is possible to determine electron capturestrength from (p,n) experiments. This approach may make it possible to obtain electron capture strength for radioactive nuclei by studying (p,n) reactions in inverse kinematics.