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Autori principali: Variansyah, Ilham, McClarren, Ryan G., Palmer, Todd S.
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2501.06391
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author Variansyah, Ilham
McClarren, Ryan G.
Palmer, Todd S.
author_facet Variansyah, Ilham
McClarren, Ryan G.
Palmer, Todd S.
contents We present an implicit collision method with on-the-fly multiplicity adjustment based on the forward weight window methodology for efficient Dynamic Monte Carlo (MC) simulation of reactivity excursion transport problems. Test problems based on the Dragon experiment of 1945 by Otto Frisch are devised to verify and assess the efficiency of the method. The test problems exhibit the key features of the Dragon experiment, namely nine orders of magnitude neutron flux bursts followed by significant post-burst delayed neutron effects. Such an extreme reactivity excursion is particularly challenging and has never been solved with Dynamic MC. The proposed implicit collision multiplicity adjustment, in conjunction with a simple forced delayed neutron precursor decay technique, profitably trades simulation precision for reduced runtime, leading to an improved figure of merit, enabling efficient Dynamic MC simulation of extreme reactivity excursions.
format Preprint
id arxiv_https___arxiv_org_abs_2501_06391
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Implicit Collision Multiplicity Adjustment for Efficient Monte Carlo Transport Simulation of Reactivity Excursion
Variansyah, Ilham
McClarren, Ryan G.
Palmer, Todd S.
Computational Physics
We present an implicit collision method with on-the-fly multiplicity adjustment based on the forward weight window methodology for efficient Dynamic Monte Carlo (MC) simulation of reactivity excursion transport problems. Test problems based on the Dragon experiment of 1945 by Otto Frisch are devised to verify and assess the efficiency of the method. The test problems exhibit the key features of the Dragon experiment, namely nine orders of magnitude neutron flux bursts followed by significant post-burst delayed neutron effects. Such an extreme reactivity excursion is particularly challenging and has never been solved with Dynamic MC. The proposed implicit collision multiplicity adjustment, in conjunction with a simple forced delayed neutron precursor decay technique, profitably trades simulation precision for reduced runtime, leading to an improved figure of merit, enabling efficient Dynamic MC simulation of extreme reactivity excursions.
title Implicit Collision Multiplicity Adjustment for Efficient Monte Carlo Transport Simulation of Reactivity Excursion
topic Computational Physics
url https://arxiv.org/abs/2501.06391