Propagation of Nuclear Data Uncertainties for ELECTRA Burn-up Calculations

Sjöstrand, Henrik; Alhassan, Erwin; Duan, Junfeng; Gustavsson, Cecilia; Koning, A. J.; Pomp, Stephan; Rochman, D.; Österlund, Michael

doi:10.1016/j.nds.2014.04.125

Cited by 17 publications

(15 citation statements)

References 2 publications

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“…The TMC approach was utilized earlier in assessing the impact of 239 Pu cross section uncertainties on the full core 3-D SERPENT [22] model of the ELEC-TRA reactor at steady state [28] and in burnup calculations [29]. In this work however, we apply the TMC method for the propagation of nuclear uncertainties of the lead coolant ( 204,206,207,208 Pb) on the following four macroscopic parameters sensitive to nuclear data: the effective multiplication factor, the coolant temperature coefficient (CTC), the coolant void worth (CVW) and the effective delayed neutron fraction at zero burnup.…”

Section: Applicationmentioning

confidence: 99%

Uncertainty and correlation analysis of lead nuclear data on reactor parameters for the European Lead Cooled Training Reactor

Alhassan

Sjöstrand

Helgesson

et al. 2015

Annals of Nuclear Energy

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The Total Monte Carlo (TMC) method was used in this study to assess the impact of 204,206,207,208 Pb nuclear data uncertainties on reactor safety parameters for the ELECTRA reactor. Relatively large uncertainties were observed in the k eff and the coolant void worth (CV W ) for all isotopes except for 204 Pb with significant contribution coming from 208 Pb nuclear data; the dominant effect came from uncertainties in the resonance parameters; however, elastic scattering cross section and the angular distributions also had significant impact. It was also observed that the k eff distribution for 206,207,208 Pb deviates from a Gaussian distribution with tails in the high k eff region. An uncertainty of 0.9% on the k ef f and 3.3% for the CV W due to lead nuclear data were obtained. As part of the work, cross section-reactor parameter correlations were also studied using a Monte Carlo sensitivity method. Strong correlations were observed between the k eff and (n, el) cross section for all the lead isotopes. The correlation between the (n, inl) and the k eff was also found to be significant.

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Section: Applicationmentioning

confidence: 99%

Uncertainty and correlation analysis of lead nuclear data on reactor parameters for the European Lead Cooled Training Reactor

Alhassan

Sjöstrand

Helgesson

et al. 2015

Annals of Nuclear Energy

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“…TENDL-2014 contains different random files for important nuclides, where all the important reactions for U235, U238 and Pu239, as well as the thermal scattering part of H1-H20 have been perturbed. This feature offers a good and pragmatic opportunity to extend the capabilities of CORES SIM -TH in order to perform uncertainty analysis (UA) via the Total Monte Carlo (TMC) method [3,4]. This is possible since after the proper processing of such random files into the common ACE format by means of the NJOY code, the computation of the energy-collapsed and homogenized macroscopic cross-sections can be performed with the Monte Carlo SERPENT code.…”

Section: Methodsmentioning

confidence: 99%

Propagation of neutron-reaction uncertainties through multi-physics models of novel LWR's

2017

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Abstract. The novel design of the renewable boiling water reactor (RBWR) allows a breeding ratio greater than unity and thus, it aims at providing for a self-sustained fuel cycle. The neutron reactions that compose the different microscopic cross-sections and angular distributions are uncertain, so when they are employed in the determination of the spatial distribution of the neutron flux in a nuclear reactor, a methodology should be employed to account for these associated uncertainties. In this work, the Total Monte Carlo (TMC) method is used to propagate the different neutron-reactions (as well as angular distributions) covariances that are part of the TENDL-2014 nuclear data (ND) library. The main objective is to propagate them through coupled neutronic and thermal-hydraulic models in order to assess the uncertainty of important safety parameters related to multi-physics, such as peak cladding temperature along the axial direction of an RBWR fuel assembly. The objective of this study is to quantify the impact that ND covariances of important nuclides such as U-235, U-238, Pu-239 and the thermal scattering of hydrogen in H2O have in the deterministic safety analysis of novel nuclear reactors designs.

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“…The term uncertainty as used in this work is represented by an estimated one standard deviation of the distribution under consideration. The TMC method has been presented extensively in several references: [3,4,19,20,21] as well as applied to many applications: [10,22,23,24,25,26,27,28,29]. The first step in our updating scheme involves the identification of model input parameters (and the corresponding parameter widths) that play significant roles in defining or characterizing the reaction observables of interest.…”

Section: Updating Schemementioning

confidence: 99%

Bayesian updating for data adjustments and multi-level uncertainty propagation within Total Monte Carlo

Alhassan

Rochman

Sjöstrand

et al. 2020

Annals of Nuclear Energy

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In this work, a method is proposed for combining differential and integral benchmark experimental data within a Bayesian framework for nuclear data adjustments and multi-level uncertainty propagation using the Total Monte Carlo method. First, input parameters to basic nuclear physics models implemented within the state of the art nuclear reactions code, TALYS, were sampled from uniform distributions and randomly varied to produce a large set of random nuclear data files. Next, a probabilistic data assimilation was carried out by computing the likelihood function for each random nuclear data file based first on only differential experimental data (1st update) and then on integral benchmark data (2nd update). The individual likelihood functions from the two updates were then combined into a global likelihood function which was used for the selection of the final 'best' file. The proposed method has been applied for the adjustment of 208 Pb in the fast neutron energy region below 20 MeV. The 'best' file from the adjustments was compared with available experimental data from the EXFOR database as well as evaluations from the major nuclear data libraries and found to compare favourably.

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Propagation of Nuclear Data Uncertainties for ELECTRA Burn-up Calculations

Cited by 17 publications

References 2 publications

Uncertainty and correlation analysis of lead nuclear data on reactor parameters for the European Lead Cooled Training Reactor

Uncertainty and correlation analysis of lead nuclear data on reactor parameters for the European Lead Cooled Training Reactor

Propagation of neutron-reaction uncertainties through multi-physics models of novel LWR's

Bayesian updating for data adjustments and multi-level uncertainty propagation within Total Monte Carlo

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