Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis

Mario Santanoceto; Marco Tiberga; Zoltán Perkó; Sandra Dulla; Danny Lathouwers

doi:10.1051/epjconf/202124715008

Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis

Mario Santanoceto, Marco Tiberga^*, Zoltán Perkó, Sandra Dulla, Danny Lathouwers

^*Corresponding author for this work

RST/Reactor Physics and Nuclear Materials

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

2 Citations (Scopus)

24 Downloads (Pure)

Abstract

Uncertainty Quantification (UQ) of numerical simulations is highly relevant in the study and design of complex systems. Among the various approaches available, Polynomial Chaos Expansion (PCE) analysis has recently attracted great interest. It belongs to non-intrusive spectral projection methods and consists of constructing system responses as polynomial functions of the stochastic inputs. The limited number of required model evaluations and the possibility to apply it to codes without any modification make this technique extremely attractive. In this work, we propose the use of PCE to perform UQ of complex, multi-physics models for liquid fueled reactors, addressing key design aspects of neutronics and thermal fluid dynamics. Our PCE approach uses Smolyak sparse grids designed to estimate the PCE coefficients. To test its potential, the PCE method was applied to a 2D problem representative of the Molten Salt Fast Reactor physics. An in-house multi-physics tool constitutes the reference model. The studied responses are the maximum temperature and the effective multiplication factor. Results, validated by comparison with the reference model on 10³ Monte-Carlo sampled points, prove the effectiveness of our PCE approach in assessing uncertainties of complex coupled models.

Original language	English
Title of host publication	International Conference on Physics of Reactors
Subtitle of host publication	Transition to a Scalable Nuclear Future, PHYSOR 2020
Editors	Marat Margulis, Partrick Blaise
Publisher	EDP Sciences - Web of Conferences
Pages	2517-2524
ISBN (Electronic)	9781713827245
DOIs	https://doi.org/10.1051/epjconf/202124715008
Publication status	Published - 2020
Event	2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 - Cambridge, United Kingdom Duration: 28 Mar 2020 → 2 Apr 2020

Publication series

Name	International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Volume	2020-March

Conference

Conference	2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020
Country/Territory	United Kingdom
City	Cambridge
Period	28/03/20 → 2/04/20

Keywords

Molten salt reactor
Multi-physics
Non-intrusive
Polynomial chaos expansion
Sensitivity analysis
Sparse grids
Uncertainty quantification

Access to Document

10.1051/epjconf/202124715008

epjconf_physor2020_15008Final published version, 1.18 MBLicence: CC BY

Cite this

Santanoceto, M., Tiberga, M., Perkó, Z., Dulla, S., & Lathouwers, D. (2020). Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis. In M. Margulis, & P. Blaise (Eds.), International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 (pp. 2517-2524). (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020; Vol. 2020-March). EDP Sciences - Web of Conferences. https://doi.org/10.1051/epjconf/202124715008

Santanoceto, Mario ; Tiberga, Marco ; Perkó, Zoltán et al. / Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis. International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. editor / Marat Margulis ; Partrick Blaise. EDP Sciences - Web of Conferences, 2020. pp. 2517-2524 (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020).

@inproceedings{21558b0efa804a91940d61e72035e52b,

title = "Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis",

abstract = "Uncertainty Quantification (UQ) of numerical simulations is highly relevant in the study and design of complex systems. Among the various approaches available, Polynomial Chaos Expansion (PCE) analysis has recently attracted great interest. It belongs to non-intrusive spectral projection methods and consists of constructing system responses as polynomial functions of the stochastic inputs. The limited number of required model evaluations and the possibility to apply it to codes without any modification make this technique extremely attractive. In this work, we propose the use of PCE to perform UQ of complex, multi-physics models for liquid fueled reactors, addressing key design aspects of neutronics and thermal fluid dynamics. Our PCE approach uses Smolyak sparse grids designed to estimate the PCE coefficients. To test its potential, the PCE method was applied to a 2D problem representative of the Molten Salt Fast Reactor physics. An in-house multi-physics tool constitutes the reference model. The studied responses are the maximum temperature and the effective multiplication factor. Results, validated by comparison with the reference model on 103 Monte-Carlo sampled points, prove the effectiveness of our PCE approach in assessing uncertainties of complex coupled models.",

keywords = "Molten salt reactor, Multi-physics, Non-intrusive, Polynomial chaos expansion, Sensitivity analysis, Sparse grids, Uncertainty quantification",

author = "Mario Santanoceto and Marco Tiberga and Zolt{\'a}n Perk{\'o} and Sandra Dulla and Danny Lathouwers",

year = "2020",

doi = "10.1051/epjconf/202124715008",

language = "English",

series = "International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020",

publisher = "EDP Sciences - Web of Conferences",

pages = "2517--2524",

editor = "Marat Margulis and Partrick Blaise",

booktitle = "International Conference on Physics of Reactors",

note = "2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020 ; Conference date: 28-03-2020 Through 02-04-2020",

}

Santanoceto, M, Tiberga, M, Perkó, Z, Dulla, S & Lathouwers, D 2020, Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis. in M Margulis & P Blaise (eds), International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020, vol. 2020-March, EDP Sciences - Web of Conferences, pp. 2517-2524, 2020 International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020, Cambridge, United Kingdom, 28/03/20. https://doi.org/10.1051/epjconf/202124715008

Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis. / Santanoceto, Mario; Tiberga, Marco; Perkó, Zoltán et al.
International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. ed. / Marat Margulis; Partrick Blaise. EDP Sciences - Web of Conferences, 2020. p. 2517-2524 (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020; Vol. 2020-March).

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

TY - GEN

T1 - Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis

AU - Santanoceto, Mario

AU - Tiberga, Marco

AU - Perkó, Zoltán

AU - Dulla, Sandra

AU - Lathouwers, Danny

PY - 2020

Y1 - 2020

N2 - Uncertainty Quantification (UQ) of numerical simulations is highly relevant in the study and design of complex systems. Among the various approaches available, Polynomial Chaos Expansion (PCE) analysis has recently attracted great interest. It belongs to non-intrusive spectral projection methods and consists of constructing system responses as polynomial functions of the stochastic inputs. The limited number of required model evaluations and the possibility to apply it to codes without any modification make this technique extremely attractive. In this work, we propose the use of PCE to perform UQ of complex, multi-physics models for liquid fueled reactors, addressing key design aspects of neutronics and thermal fluid dynamics. Our PCE approach uses Smolyak sparse grids designed to estimate the PCE coefficients. To test its potential, the PCE method was applied to a 2D problem representative of the Molten Salt Fast Reactor physics. An in-house multi-physics tool constitutes the reference model. The studied responses are the maximum temperature and the effective multiplication factor. Results, validated by comparison with the reference model on 103 Monte-Carlo sampled points, prove the effectiveness of our PCE approach in assessing uncertainties of complex coupled models.

AB - Uncertainty Quantification (UQ) of numerical simulations is highly relevant in the study and design of complex systems. Among the various approaches available, Polynomial Chaos Expansion (PCE) analysis has recently attracted great interest. It belongs to non-intrusive spectral projection methods and consists of constructing system responses as polynomial functions of the stochastic inputs. The limited number of required model evaluations and the possibility to apply it to codes without any modification make this technique extremely attractive. In this work, we propose the use of PCE to perform UQ of complex, multi-physics models for liquid fueled reactors, addressing key design aspects of neutronics and thermal fluid dynamics. Our PCE approach uses Smolyak sparse grids designed to estimate the PCE coefficients. To test its potential, the PCE method was applied to a 2D problem representative of the Molten Salt Fast Reactor physics. An in-house multi-physics tool constitutes the reference model. The studied responses are the maximum temperature and the effective multiplication factor. Results, validated by comparison with the reference model on 103 Monte-Carlo sampled points, prove the effectiveness of our PCE approach in assessing uncertainties of complex coupled models.

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KW - Multi-physics

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M3 - Conference contribution

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EP - 2524

BT - International Conference on Physics of Reactors

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Santanoceto M, Tiberga M, Perkó Z, Dulla S, Lathouwers D. Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis. In Margulis M, Blaise P, editors, International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020. EDP Sciences - Web of Conferences. 2020. p. 2517-2524. (International Conference on Physics of Reactors: Transition to a Scalable Nuclear Future, PHYSOR 2020). doi: 10.1051/epjconf/202124715008

Uncertainty quantification in steady state simulations of a molten salt system using polynomial chaos expansion analysis

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