Abstract
A new theoretical framework has been established and applied in the calculation of electron capture (EC) and β-decay rates in stellar environment, characterized by high density and temperature. For the description of the nuclear properties, the finite-temperature Hartree Bardeen-Cooper-Schrie_er (FTHBCS) theory based on the relativistic derivative-coupling D3C* interaction is employed. In order to describe the charge-exchange transitions, the finitetemperature proton-neutron quasi-particle random-phase approximation is developed (FT-PNRQRPA) which includes both temperature and pairing correlations. In the FT-HBCS calculations, only the isovector pairing is included, while in the residual interaction of the FT-PNRQRPA both the isovector and isoscalar pairing contribute. In this work, results for EC and β-decay rates are presented in the temperature interval T = 0–1.5 MeV and stellar density ρYe = 107 and 109 g/cm3. Both allowed 0+, 1+ and first-forbidden transitions 0−, 1− and 2− are included in the calculations. It is shown that interplay between pairing correlations and finite-temperature effects can lead to significant changes in rates. It is also important to include de-excitations, i.e. transitions with negative Q-value, that become increasingly significant at higher temperatures especially for p f -shell nuclei.
Highlights
Reactions mediated by the weak force are of significant importance for nuclear and particle physics, as well as nuclear astrophysics, where they specify the dynamics of core-collapse supernovae (CCSNe) and the time-scale of r-process
Developed FT-HBCS+FT-PNRQRPA based on the relativistic D3C∗ derivative coupling interaction has been applied to study both the electron capture (EC) and β-decay rates in presupernova conditions
Our model allows us to study the interplay between finite-temperature and pairing correlation effects, as well as their influence on reactions mediated by the weak force
Summary
Reactions mediated by the weak force are of significant importance for nuclear and particle physics, as well as nuclear astrophysics, where they specify the dynamics of core-collapse supernovae (CCSNe) and the time-scale of r-process. It is necessary to develop a robust theoretical framework for the description of key weak force reactions under extreme conditions of density and temperature. First steps toward this direction were made some time ago by Fuller, Fowler and Newman in Refs. We have developed a theoretical framework for the calculation of the nuclear charge-exchange transitions in open-shell nuclei at finite temperatures, based on the relativistic nuclear EDFs. The proton-neutron relativistic quasi-particle RPA (FT-PNRQRPA) has been applied on top of the FT-HBCS to calculate the relevant charge-exchange transitions alongside the EC and β-decay rates [15,16,17]. We use the same model to study the temperature dependence of EC and β-decay rates of selected Ti and Fe nuclei
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