Threshold-Aligned Pygmy Dipole Strength in Astrophysical (n,γ) and (γ,n) Reactions
Abstract
Reaction-rate calculations relevant to r-process nucleosynthesis depend sensitively on the nuclear γ-strength function (γSF). Here we investigate the impact of low-lying pygmy dipole strength (PDS) in (n,γ) and (γ,n) reactions using γSF based on relativistic nuclear energy density functional theory and propagate these strengths into Hauser--Feshbach statistical model calculations of the reaction rates. We show that considerable reaction-rate enhancements at temperatures relevant for r-process nucleosynthesis are governed by the alignment of the pygmy dipole strength energy with the neutron separation threshold Sn rather than by the total low-energy strength. Consequently, nuclei such as 68Ni and 132Sn, where the PDS energy-Sn alignment occurs, exhibit the strongest effects on reaction-rate enhancements. These results demonstrate that modeling reliable reaction rates in r-process nucleosynthesis necessitates accurate microscopic descriptions of low-energy dipole strength, in close synergy with experimental investigations in the vicinity of neutron threshold.
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