Investigation of novel weight window methods in Serpent 2 for fusion neutronics applications

Investigation of novel weight window methods in Serpent 2 for fusion neutronics applications

•Application of Serpent 2 Monte Carlo code for nuclear fusion-relevant spectra and geometries.•Application of novel weight window methods in Serpent 2 to deep shielding problems•Benchmarking of Serpent 2 nuclear responses against SINBAD experimental data and MCNP. Released in 2009, the Serpent Monte...

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Bibliographic Details
Published in:Fusion engineering and design Vol. 178; p. 113090
Main Authors: Valentine, A., Worrall, R., Leppänen, J.
Format: Journal Article
Language:English
Published: Amsterdam Elsevier B.V 01-05-2022
Elsevier Science Ltd
Subjects:
DEMO
MCNP
Neutronics
Nuclear fission
Nuclear fusion
Nuclear reactors
Particle interactions
Photons
Reactor physics
Serpent
SINBAD
Systems analysis
Variance reduction
Serpent
Neutronics
MCNP
DEMO
SINBAD
Variance reduction
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Summary:•Application of Serpent 2 Monte Carlo code for nuclear fusion-relevant spectra and geometries.•Application of novel weight window methods in Serpent 2 to deep shielding problems•Benchmarking of Serpent 2 nuclear responses against SINBAD experimental data and MCNP. Released in 2009, the Serpent Monte Carlo code has established itself as a highly efficient and powerful simulation code for nuclear systems analysis. Originally developed for reactor physics applications, the scope of the code now extends to coupled multi-physics simulations and photon transport. The latter has allowed adoption of the code by the fusion neutronics community following developments of a coupled neutron-photon capability in 2014 and the ability to handle complex geometry types in 2016. The code is well validated for the energy regimes and geometry types one can expect in fission reactor analysis. Over the course of recent years a benchmarking effort has been undertaken for application of the code to nuclear fusion. Compared to nuclear fission, or accelerator based applications, the underlying particle interaction phenomena differ greatly at the energies expected in a fusion reactor as well as the specific responses that are of interest. In this paper, a novel weight window generation implementation in Serpent is investigated. The applicability of this method is demonstrated for the Frascati Neutron Generator (FNG) bulk blanket and shield experiment, part of the SINBAD database, and a DEMO helium cooled pebble bed (HCPB) computational model. A comparison is performed against MCNP using weight windows generated with ADVANTG. Excellent agreement is found for the specified tallies and the significant efficiency gain using weight windows generated using both methods is comparable. A robust variance reduction method implementation is fundamental to applications to fusion neutronics and as such, this work is an important step in deployment of Serpent for this type of analysis.
ISSN:0920-3796
1873-7196
DOI:10.1016/j.fusengdes.2022.113090