Uncertainty quantification for severe-accident reactor modelling: Results and conclusions of the MUSA reactor applications work package

S. Brumm; F. Gabrielli; V. Sanchez Espinoza; A. Stakhanova; P. Groudev; P. Petrova; P. Vryashkova; P. Ou; W. Zhang; A. Malkhasyan; L. E. Herranz; R. Iglesias Ferrer; M. Angelucci; M. Berdaï; F. Mascari; G. Agnello; O. Sevbo; A. Iskra; V. Martinez Quiroga; M. Nudi; A. Hoefer; E. M. Pauli; S. Beck; L. Tiborcz; O. Coindreau; G. Clark; I. Lamont; X. Zheng; K. Kubo; B. Lee; M. Valincius; M. Malicki; T. Lind; Y. Vorobyov; O. Kotsuba; M. Di Giuli; I. Ivanov; M. D'Onorio; F. Giannetti; Tuomo Sevon

doi:10.1016/j.anucene.2024.110962

Uncertainty quantification for severe-accident reactor modelling: Results and conclusions of the MUSA reactor applications work package

S. Brumm^*
, F. Gabrielli
, V. Sanchez Espinoza
, A. Stakhanova
, P. Groudev
, P. Petrova
, P. Vryashkova
, P. Ou
, W. Zhang
, A. Malkhasyan
, L. E. Herranz
, R. Iglesias Ferrer
, M. Angelucci
, M. Berdaï
, F. Mascari
, G. Agnello
, O. Sevbo
, A. Iskra
, V. Martinez Quiroga
, M. Nudi

A. Hoefer, E. M. Pauli, S. Beck, L. Tiborcz, O. Coindreau, G. Clark, I. Lamont, X. Zheng, K. Kubo, B. Lee, M. Valincius, M. Malicki, T. Lind, Y. Vorobyov, O. Kotsuba, M. Di Giuli, I. Ivanov, M. D'Onorio, F. Giannetti, Tuomo Sevon

^*Corresponding author for this work

BA4503 Severe accident analysis

European Commission
Karlsruhe Institute of Technology (KIT)
Bulgarian Academy of Sciences
China Nuclear Power Technology Research Institute Co., Ltd.
BEL-V
Centro de Investigaciones Energéticas, Medioambientales y Tecnológicas (CIEMAT)
Canadian Nuclear Safety Commission (CNSC)
National Agency for New Technologies, Energy and Sustainable Economic Development (ENEA)
Energorisk Ltd.
Energy Software S.L. (ENSO)
Electric Power Research Institute Inc.
Framatome GmbH
Forschungsgelände Garching
Institute for Radiological Protection and Nuclear Safety (IRSN)
Jacobs, UK
Japan Atomic Energy Agency
Korea Atomic Energy Research Institute (KAERI)
Lithuanian Energy Institute (LEI)
Paul Scherrer Institute (PSI)
State Scientific and Technical Center for Nuclear and Radiation Safety (SSTC NRS)
Tractebel Engie
Technical University of Sofia
Sapienza University of Rome

Research output: Contribution to journal › Article › Scientific › peer-review

15 Citations (Scopus)

Abstract

The recently completed Horizon-2020 project “Management and Uncertainties of Severe Accidents (MUSA)” has reviewed uncertainty sources and Uncertainty Quantification methodology for assessing Severe Accidents (SA), and has made a substantial effort at stimulating uncertainty applications in predicting the radiological Source Term of reactor and Spent Fuel Pool accident scenarios. The key motivation of the project has been to bring the advantages of the Best Estimate Plus Uncertainty approach to the field of Severe Accident modelling. With respect to deterministic analyses, expected gains are avoiding adopting conservative assumptions, identifying uncertainty bands of estimates, and gaining insights into dominating uncertain parameters. Also, the benefits for understanding and improving Accident Management were to be explored. The reactor applications brought together a large group of participants that set out to apply uncertainty analysis (UA) within their field of SA modelling expertise – in particular reactor types, but also SA code used (ASTEC, MELCOR, MAAP, RELAP/SCDAPSIM), uncertainty quantification tools used (DAKOTA, SUSA, URANIE, self-developed tools based on Python code), detailed accident scenarios, and in some cases SAM actions. The setting up of the analyses, challenges faced during that phase, and solutions explored, are described in Brumm et al. ANE 191 (2023). This paper synthesizes the reactor-application work at the end of the project. Analyses of 23 partners are presented in different categories, depending on whether their main goal is/are (i) uncertainty bands of simulation results; (ii) the understanding of dominating uncertainties in specific sub-models of the SA code; (iii) improving the understanding of specific accident scenarios, with or without the application of SAM actions; or, (iv) a demonstration of the tools used and developed, and of the capability to carry out an uncertainty analysis in the presence of the challenges faced. A cross-section of the partners’ results is presented and briefly discussed, to provide an overview of the work done, and to encourage accessing and studying the project deliverables that are open to the public. Furthermore, the partners’ experiences made during the project have been evaluated and are presented as good practice recommendations. The paper ends with conclusions on the level of readiness of UA in SA modelling, on the determination of governing uncertainties, and on the analysis of SAM actions.

Original language	English
Article number	110962
Journal	Annals of Nuclear Energy
Volume	211
DOIs	https://doi.org/10.1016/j.anucene.2024.110962
Publication status	Published - Feb 2025
MoE publication type	A1 Journal article-refereed

Funding

The MUSA project has received funding from the Euratom research and training programme 2014 \u2013 2018 under grant agreement No. 847441. This paper reflects only the authors\u2019 view; the European Commission is not responsible for any use that may be made of the information it contains.

Keywords

Modelling
MUSA
Nuclear reactor
Severe accident
Source term
Uncertainty quantification

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Brumm, S., Gabrielli, F., Sanchez Espinoza, V., Stakhanova, A., Groudev, P., Petrova, P., Vryashkova, P., Ou, P., Zhang, W., Malkhasyan, A., Herranz, L. E., Iglesias Ferrer, R., Angelucci, M., Berdaï, M., Mascari, F., Agnello, G., Sevbo, O., Iskra, A., Martinez Quiroga, V., ... Sevon, T. (2025). Uncertainty quantification for severe-accident reactor modelling: Results and conclusions of the MUSA reactor applications work package. Annals of Nuclear Energy, 211, Article 110962. https://doi.org/10.1016/j.anucene.2024.110962

@article{bbb8dcabff4c458285f95e0701ffc445,

title = "Uncertainty quantification for severe-accident reactor modelling: Results and conclusions of the MUSA reactor applications work package",

abstract = "The recently completed Horizon-2020 project “Management and Uncertainties of Severe Accidents (MUSA)” has reviewed uncertainty sources and Uncertainty Quantification methodology for assessing Severe Accidents (SA), and has made a substantial effort at stimulating uncertainty applications in predicting the radiological Source Term of reactor and Spent Fuel Pool accident scenarios. The key motivation of the project has been to bring the advantages of the Best Estimate Plus Uncertainty approach to the field of Severe Accident modelling. With respect to deterministic analyses, expected gains are avoiding adopting conservative assumptions, identifying uncertainty bands of estimates, and gaining insights into dominating uncertain parameters. Also, the benefits for understanding and improving Accident Management were to be explored. The reactor applications brought together a large group of participants that set out to apply uncertainty analysis (UA) within their field of SA modelling expertise – in particular reactor types, but also SA code used (ASTEC, MELCOR, MAAP, RELAP/SCDAPSIM), uncertainty quantification tools used (DAKOTA, SUSA, URANIE, self-developed tools based on Python code), detailed accident scenarios, and in some cases SAM actions. The setting up of the analyses, challenges faced during that phase, and solutions explored, are described in Brumm et al. ANE 191 (2023). This paper synthesizes the reactor-application work at the end of the project. Analyses of 23 partners are presented in different categories, depending on whether their main goal is/are (i) uncertainty bands of simulation results; (ii) the understanding of dominating uncertainties in specific sub-models of the SA code; (iii) improving the understanding of specific accident scenarios, with or without the application of SAM actions; or, (iv) a demonstration of the tools used and developed, and of the capability to carry out an uncertainty analysis in the presence of the challenges faced. A cross-section of the partners{\textquoteright} results is presented and briefly discussed, to provide an overview of the work done, and to encourage accessing and studying the project deliverables that are open to the public. Furthermore, the partners{\textquoteright} experiences made during the project have been evaluated and are presented as good practice recommendations. The paper ends with conclusions on the level of readiness of UA in SA modelling, on the determination of governing uncertainties, and on the analysis of SAM actions.",

keywords = "Modelling, MUSA, Nuclear reactor, Severe accident, Source term, Uncertainty quantification",

author = "S. Brumm and F. Gabrielli and \{Sanchez Espinoza\}, V. and A. Stakhanova and P. Groudev and P. Petrova and P. Vryashkova and P. Ou and W. Zhang and A. Malkhasyan and Herranz, \{L. E.\} and \{Iglesias Ferrer\}, R. and M. Angelucci and M. Berda{\"i} and F. Mascari and G. Agnello and O. Sevbo and A. Iskra and \{Martinez Quiroga\}, V. and M. Nudi and A. Hoefer and Pauli, \{E. M.\} and S. Beck and L. Tiborcz and O. Coindreau and G. Clark and I. Lamont and X. Zheng and K. Kubo and B. Lee and M. Valincius and M. Malicki and T. Lind and Y. Vorobyov and O. Kotsuba and \{Di Giuli\}, M. and I. Ivanov and M. D'Onorio and F. Giannetti and Tuomo Sevon",

year = "2025",

month = feb,

doi = "10.1016/j.anucene.2024.110962",

language = "English",

volume = "211",

journal = "Annals of Nuclear Energy",

issn = "0306-4549",

publisher = "Elsevier",

}

Brumm, S, Gabrielli, F, Sanchez Espinoza, V, Stakhanova, A, Groudev, P, Petrova, P, Vryashkova, P, Ou, P, Zhang, W, Malkhasyan, A, Herranz, LE, Iglesias Ferrer, R, Angelucci, M, Berdaï, M, Mascari, F, Agnello, G, Sevbo, O, Iskra, A, Martinez Quiroga, V, Nudi, M, Hoefer, A, Pauli, EM, Beck, S, Tiborcz, L, Coindreau, O, Clark, G, Lamont, I, Zheng, X, Kubo, K, Lee, B, Valincius, M, Malicki, M, Lind, T, Vorobyov, Y, Kotsuba, O, Di Giuli, M, Ivanov, I, D'Onorio, M, Giannetti, F & Sevon, T 2025, 'Uncertainty quantification for severe-accident reactor modelling: Results and conclusions of the MUSA reactor applications work package', Annals of Nuclear Energy, vol. 211, 110962. https://doi.org/10.1016/j.anucene.2024.110962

TY - JOUR

T1 - Uncertainty quantification for severe-accident reactor modelling

T2 - Results and conclusions of the MUSA reactor applications work package

AU - Brumm, S.

AU - Gabrielli, F.

AU - Sanchez Espinoza, V.

AU - Stakhanova, A.

AU - Groudev, P.

AU - Petrova, P.

AU - Vryashkova, P.

AU - Ou, P.

AU - Zhang, W.

AU - Malkhasyan, A.

AU - Herranz, L. E.

AU - Iglesias Ferrer, R.

AU - Angelucci, M.

AU - Berdaï, M.

AU - Mascari, F.

AU - Agnello, G.

AU - Sevbo, O.

AU - Iskra, A.

AU - Martinez Quiroga, V.

AU - Nudi, M.

AU - Hoefer, A.

AU - Pauli, E. M.

AU - Beck, S.

AU - Tiborcz, L.

AU - Coindreau, O.

AU - Clark, G.

AU - Lamont, I.

AU - Zheng, X.

AU - Kubo, K.

AU - Lee, B.

AU - Valincius, M.

AU - Malicki, M.

AU - Lind, T.

AU - Vorobyov, Y.

AU - Kotsuba, O.

AU - Di Giuli, M.

AU - Ivanov, I.

AU - D'Onorio, M.

AU - Giannetti, F.

AU - Sevon, Tuomo

PY - 2025/2

Y1 - 2025/2

N2 - The recently completed Horizon-2020 project “Management and Uncertainties of Severe Accidents (MUSA)” has reviewed uncertainty sources and Uncertainty Quantification methodology for assessing Severe Accidents (SA), and has made a substantial effort at stimulating uncertainty applications in predicting the radiological Source Term of reactor and Spent Fuel Pool accident scenarios. The key motivation of the project has been to bring the advantages of the Best Estimate Plus Uncertainty approach to the field of Severe Accident modelling. With respect to deterministic analyses, expected gains are avoiding adopting conservative assumptions, identifying uncertainty bands of estimates, and gaining insights into dominating uncertain parameters. Also, the benefits for understanding and improving Accident Management were to be explored. The reactor applications brought together a large group of participants that set out to apply uncertainty analysis (UA) within their field of SA modelling expertise – in particular reactor types, but also SA code used (ASTEC, MELCOR, MAAP, RELAP/SCDAPSIM), uncertainty quantification tools used (DAKOTA, SUSA, URANIE, self-developed tools based on Python code), detailed accident scenarios, and in some cases SAM actions. The setting up of the analyses, challenges faced during that phase, and solutions explored, are described in Brumm et al. ANE 191 (2023). This paper synthesizes the reactor-application work at the end of the project. Analyses of 23 partners are presented in different categories, depending on whether their main goal is/are (i) uncertainty bands of simulation results; (ii) the understanding of dominating uncertainties in specific sub-models of the SA code; (iii) improving the understanding of specific accident scenarios, with or without the application of SAM actions; or, (iv) a demonstration of the tools used and developed, and of the capability to carry out an uncertainty analysis in the presence of the challenges faced. A cross-section of the partners’ results is presented and briefly discussed, to provide an overview of the work done, and to encourage accessing and studying the project deliverables that are open to the public. Furthermore, the partners’ experiences made during the project have been evaluated and are presented as good practice recommendations. The paper ends with conclusions on the level of readiness of UA in SA modelling, on the determination of governing uncertainties, and on the analysis of SAM actions.

AB - The recently completed Horizon-2020 project “Management and Uncertainties of Severe Accidents (MUSA)” has reviewed uncertainty sources and Uncertainty Quantification methodology for assessing Severe Accidents (SA), and has made a substantial effort at stimulating uncertainty applications in predicting the radiological Source Term of reactor and Spent Fuel Pool accident scenarios. The key motivation of the project has been to bring the advantages of the Best Estimate Plus Uncertainty approach to the field of Severe Accident modelling. With respect to deterministic analyses, expected gains are avoiding adopting conservative assumptions, identifying uncertainty bands of estimates, and gaining insights into dominating uncertain parameters. Also, the benefits for understanding and improving Accident Management were to be explored. The reactor applications brought together a large group of participants that set out to apply uncertainty analysis (UA) within their field of SA modelling expertise – in particular reactor types, but also SA code used (ASTEC, MELCOR, MAAP, RELAP/SCDAPSIM), uncertainty quantification tools used (DAKOTA, SUSA, URANIE, self-developed tools based on Python code), detailed accident scenarios, and in some cases SAM actions. The setting up of the analyses, challenges faced during that phase, and solutions explored, are described in Brumm et al. ANE 191 (2023). This paper synthesizes the reactor-application work at the end of the project. Analyses of 23 partners are presented in different categories, depending on whether their main goal is/are (i) uncertainty bands of simulation results; (ii) the understanding of dominating uncertainties in specific sub-models of the SA code; (iii) improving the understanding of specific accident scenarios, with or without the application of SAM actions; or, (iv) a demonstration of the tools used and developed, and of the capability to carry out an uncertainty analysis in the presence of the challenges faced. A cross-section of the partners’ results is presented and briefly discussed, to provide an overview of the work done, and to encourage accessing and studying the project deliverables that are open to the public. Furthermore, the partners’ experiences made during the project have been evaluated and are presented as good practice recommendations. The paper ends with conclusions on the level of readiness of UA in SA modelling, on the determination of governing uncertainties, and on the analysis of SAM actions.

KW - Modelling

KW - MUSA

KW - Nuclear reactor

KW - Severe accident

KW - Source term

KW - Uncertainty quantification

UR - https://www.scopus.com/pages/publications/85206004987

U2 - 10.1016/j.anucene.2024.110962

DO - 10.1016/j.anucene.2024.110962

M3 - Article

AN - SCOPUS:85206004987

SN - 0306-4549

VL - 211

JO - Annals of Nuclear Energy

JF - Annals of Nuclear Energy

M1 - 110962

ER -

Uncertainty quantification for severe-accident reactor modelling: Results and conclusions of the MUSA reactor applications work package

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