Journal
PHYSICAL REVIEW C
Volume 104, Issue 4, Pages -Publisher
AMER PHYSICAL SOC
DOI: 10.1103/PhysRevC.104.044321
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Funding
- QuantiXLie Centre of Excellence
- Croatian Government
- European Union through the European Regional Development Fund
- Competitiveness and Cohesion Operational Programme [KK.01.1.1.01]
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A theoretical framework based on relativistic nuclear energy density-functional and statistical models is introduced in this study to describe the rates of beta-delayed neutron emission and fission. The calculated data are compared with experimental results, showing a certain level of agreement. Further studies on fission barrier data are needed to evaluate the sensitivity of r-process nucleosynthesis on nuclear fission.
Background: beta-delayed neutron emission and fission are essential in r-process nucleosynthesis. Although the number of experimental studies covering r-process nuclei has recently increased, the uncertainties of beta-delayed neutron emission and fission are still large for r-process simulations. Purpose: Our aim is to introduce a theoretical framework for the description of beta-delayed neutron-emission and fission rates based on relativistic nuclear energy density-functional and statistical models and investigate their properties throughout the nuclide map. Methods: To obtain beta strength functions, the relativistic proton-neutron quasiparticle random-phase approximation is employed. Particle evaporations and fission from highly excited nuclear states are estimated by the Hauser-Feshbach statistical model. beta-delayed neutron branching ratios P-n are calculated and compared with experimental data, and the beta-delayed fission branching ratio P-f are also assessed by using different fission barrier data. Results: Calculated P-n are in a good agreement with the experimental data and the root mean square deviation is comparable to results of preceding works. It is found that energy withdrawal by beta-delayed neutron-emission sensitivity varies P-n especially for nuclei near the neutron drip line. P-f-depend sensitively on fission barrier data. It is found that not only the barrier height but also the number of barrier humps is important to evaluate P-f . Conclusions: The framework introduced in this work provides an improved theoretical description of the beta-delayed neutron emission and fission. Since P-f as well as P-n depend strongly on fission barrier information, four kinds of fission barrier data are used in this work to allow further sensitivity studies of the r-process nucleosynthesis on the nuclear fission. More studies on fission barrier are highly requested to assess the role of j-delayed fission in the r-process study. A complete set of calculated data for beta-delayed neutron emission and fission are summarized as a table in supplemental material for its use in r-process studies as well as to complement a part of nuclear data in which no experimental data are available.
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