GEF裂变产率辐照后检验数据的同化

IF 0.9 Q3 NUCLEAR SCIENCE & TECHNOLOGY

EPJ Nuclear Sciences & Technologies Pub Date : 2020-01-01 DOI:10.1051/epjn/2020015

D. Siefman, M. Hursin, H. Sjöstrand, G. Schnabel, D. Rochman, A. Pautz

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引用次数: 8

摘要

核数据，特别是裂变产率，在乏燃料中裂变产物的预测浓度中产生不确定性，这可能超过工程目标精度。在此，我们提出了一个新的框架，将数据同化方法扩展到使用辐照后检查实验的燃烧模拟。调整后的裂变产率降低了偏差，降低了模拟的不确定性。我们的方法调整代码GEF的模型参数。我们比较了BFMC和MOCABA方法对数据同化的影响，特别关注了GEF裂变产率的非正态性的影响。在我们提出的应用中，最好的数据同化框架将模拟的平均偏差从26%降低到14%。平均相对标准偏差从21%下降到14%。数据同化后的GEF裂变产率与JEFF3.3的结果吻合较好。对于Pu-239热裂变，同化前与JEFF3.3的平均相对差异为16%，同化后与JEFF3.3的平均相对差异为12%。对于裂变产率的标准差，同化前的GEF比同化后的JEFF3.3大100%，同化后的GEF只比同化后的JEFF3.3大4%。边际似然优化方法表明，积分数据的不一致性对MOCABA有重要影响。当不使用该方法时，MOCABA调整的裂变产率使模拟的偏差加重了30%。BFMC表明它固有地解释了这种不一致。与不应用边际似然优化相比，应用边际似然优化与BFMC的偏差降低了2%，但结果更差收敛。

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Data assimilation of post-irradiation examination data for fission yields from GEF

Nuclear data, especially fission yields, create uncertainties in the predicted concentrations of fission products in spent fuel which can exceed engineering target accuracies. Herein, we present a new framework that extends data assimilation methods to burnup simulations by using post-irradiation examination experiments. The adjusted fission yields lowered the bias and reduced the uncertainty of the simulations. Our approach adjusts the model parameters of the code GEF. We compare the BFMC and MOCABA approaches to data assimilation, focusing especially on the effects of the non-normality of GEF’s fission yields. In the application that we present, the best data assimilation framework decreased the average bias of the simulations from 26% to 14%. The average relative standard deviation decreased from 21% to 14%. The GEF fission yields after data assimilation agreed better with those in JEFF3.3. For Pu-239 thermal fission, the average relative difference from JEFF3.3 was 16% before data assimilation and after it was 12%. For the standard deviations of the fission yields, GEF’s were 100% larger than JEFF3.3’s before data assimilation and after were only 4% larger. The inconsistency of the integral data had an important effect on MOCABA, as shown with the Marginal Likelihood Optimization method. When the method was not applied, MOCABA’s adjusted fission yields worsened the bias of the simulations by 30%. BFMC showed that it inherently accounted for this inconsistency. Applying Marginal Likelihood Optimization with BFMC gave a 2% lower bias compared to not applying it, but the results were more poorly converged.

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来源期刊

EPJ Nuclear Sciences & Technologies NUCLEAR SCIENCE & TECHNOLOGY-

CiteScore

1.00

自引率

20.00%

发文量

审稿时长

10 weeks