Theoretical Calculations of n+56Fe Reaction
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摘要: 应用光学模型、核内级联模型、激子模型(含改进的Iwamoto-Harada模型)、统一的Hauser-Feshbach理论以及扭曲波玻恩近似理论,对入射能量在20 MeV以下中子与56Fe非弹性散射反应的γ产生截面、分立能级截面和总的非弹性散射截面进行计算,并与最新实验数据以及来自ENDF/B-VII、JEFF-3.1和JENDL-4库的评价数据进行比较和分析。结果显示,理论计算结果与实验数据符合较好,并且对于有些激发态的非弹性散射截面我们的计算结果优于ENDF/B-VII,JEFF-3.1和JENDL-4库的评价结果。
The gamma production, level production and total inelastic scattering cross sections are calculated at incident neutron energy below 20 MeV. The optical model, the intra-nuclear cascade model, the exciton model (including improved Iwamoto-Harada model), the uni ed Hauser-Feshbach theory and the distorted wave Born approximation theory are used. Theoretical calculated results are compared with the recent experimental data and other evaluated data from ENDF/B-VII, JEFF-3.1, and JENDL-4. It is found that our calculated results agree with the experimental data and the calculated results for some level cross sections are more consistent with the related experimental data than the results from ENDF/B-VII, JEFF-3.1, and JENDL-4 data base.Abstract: The gamma production, level production and total inelastic scattering cross sections are calculated at incident neutron energy below 20 MeV. The optical model, the intra-nuclear cascade model, the exciton model (including improved Iwamoto-Harada model), the uni ed Hauser-Feshbach theory and the distorted wave Born approximation theory are used. Theoretical calculated results are compared with the recent experimental data and other evaluated data from ENDF/B-VII, JEFF-3.1, and JENDL-4. It is found that our calculated results agree with the experimental data and the calculated results for some level cross sections are more consistent with the related experimental data than the results from ENDF/B-VII, JEFF-3.1, and JENDL-4 data base. -
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