First evidence of enhanced low-energy γ-ray strength from thermal neutron capture data

Abstract

The γ-ray strength function, or average reduced γ-ray transition probability, is a fundamental input in the calculation of (n,γ) cross sections used to simulate the nucleosynthesis of elements heavier than Fe. Since 2004, an enhanced probability of γ-decay with γ-ray energies below ≈2 - 4 MeV has been measured in reaction data for numerous nuclei. This has been observed as an increase in the γ-ray strength with decreasing γ-ray energy, often referred to as the low-energy enhancement or upbend in the γ-ray strength. Nevertheless, the available data confirming this enhancement corresponded solely to charged-particle included reactions and no low-energy enhancement had yet been confirmed from neutron-induced reaction measurements. In this work, we present the first evidence of low-energy γ-ray strength enhancement from neutron-capture reaction data. Gamma-ray spectra following thermal neutron capture on 58,60Ni have been used to determine the strength for primary and secondary γ-rays in 59,61Ni, showing an enhancement for γ-ray energies below ≈ 3 MeV and ≈ 2 MeV for 59,61Ni, respectively. For the first time, this enhancement is observed down to γ-ray energies of ≈0.2 MeV. Further, available spin-parity assignments have been used to obtain the multipolarity and electromagnetic character of these transitions, showing that this low-energy enhancement is dominated by M1 and E2 strength, with E1 strength also exceeding Standard Lorentzian Model predictions. Finally, large-basis shell-model calculations have been performed, also predicting a strong M1 enhancement at low γ-ray energies.