New evaluation of neutron-induced displacement damage cross section for EUROFER97

•Neutron-induced displacement damage cross section is re-evaluated for EUROFER97.•Damage cross section of 56Fe is significantly increased by addressing the issue in the JEFF-3.3 file.•Damage cross sections of EUROFER97 integrate the improvements on nuclear data for all compositions.•The evaluated da...

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Bibliographic Details
Published inNuclear materials and energy Vol. 33; p. 101284
Main Author Chen, Shengli
Format Journal Article
LanguageEnglish
Published Elsevier Ltd 01.10.2022
Elsevier
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Summary:•Neutron-induced displacement damage cross section is re-evaluated for EUROFER97.•Damage cross section of 56Fe is significantly increased by addressing the issue in the JEFF-3.3 file.•Damage cross sections of EUROFER97 integrate the improvements on nuclear data for all compositions.•The evaluated damage cross section is higher than the previous KIT evaluation by 5–8 % for D-T fusion.•Conversion factors from (fast) neutron fluences to DPA levels are calculated for simple applications. Neutron irradiation damage is an important issue in fusion reactor applications. The present work evaluates the neutron-induced displacement damage cross section of the EUROFER97 reduced activation alloy based on the state-of-the-art neutron reaction data libraries JEFF-3.3 and ENDF/B-VIII.0. The issues related to nuclear data and their processing have been considered for evaluating reliable damage cross section for EUROFER97. In addition to the recently published improvements for EUROFER97 compositions, the JEFF-3.3-based damage cross section of 56Fe is significantly increased by treating the questionable recoil energy distributions for continuum inelastic neutron scattering. The final evaluation combines the revised JEFF-3.3 and ENDF/B-VIII.0 calculations and the KIT evaluation in 2015. The athermal recombination-corrected one is also calculated by using the above evaluation and the neutron energy-dependent efficiency deduced from the two KIT evaluations. The current evaluations are higher than the KIT evaluations by 8 % for a D-T fusion neutron and by 5–6 % for an ITER first wall neutron spectrum. The conversion factors from (fast) neutron fluences to DPA levels are included for simple applications.
ISSN:2352-1791
2352-1791
DOI:10.1016/j.nme.2022.101284