Multischeme equivalence procedure for neutron transport finite element methods

Labouré, Vincent; Wang, Yaqi; Ortensi, Javier; Martin, Nicolas; Schunert, Sebastian

doi:10.1016/j.anucene.2021.108712

Title: Multischeme equivalence procedure for neutron transport finite element methods

Journal Article · Tue Feb 01 00:00:00 EST 2022 · Annals of Nuclear Energy

DOI:https://doi.org/10.1016/j.anucene.2021.108712· OSTI ID:1823669

Labouré, Vincent; Wang, Yaqi; Ortensi, Javier; Martin, Nicolas; Schunert, Sebastian

Diffusion equivalence theory applied at the full-core level is well understood and enables preservation of the multiplication factor and key reaction rates. In many cases, however, high-interest regions inside the reactor benefit from a heterogeneous representation solved using a transport scheme. This paper formalizes the multischeme (MS) equivalence procedure in which the capability to use distinct transport operator approximations in different parts of the domain is combined with an equivalence procedure, thus enforcing preservation of the reaction rates in---and (optionally) leakage rates out of---the low-resolution domains, using Super Homogenization (SPH) and discontinuity factors (DFs). Two approaches are proposed: MS-SPH applies SPH factors to the diffusion interface terms, %to obtain a flux closer to the reference whereas MS-SPH-DF relies on DFs to enforce preservation of the net currents at the interface---in which case, one normalization factor per energy group and connected region is required. The main targeted applications of multischeme equivalence are (1) more accurate reaction rates inside the heterogeneous region and (2) the ability to rely on methods otherwise incompatible with equivalence. Both proposed methods can successfully reproduce the eigenvalue and reaction rates in the heterogeneous region. Although MS-SPH-DF may better capture local effects with very refined meshes, MS-SPH otherwise seems more appealing, due to its comparable accuracy with coarser meshes and its significantly reduced burden on the analyst for large applications, as reference currents are not needed. When global quantities of interest are specifically targeted (e.g., control rod worth), neither method appears superior to a standard, spatially restricted SPH approach.

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Research Organization:: Idaho National Laboratory (INL), Idaho Falls, ID (United States)

Sponsoring Organization:: USDOE Office of Nuclear Energy (NE)

Grant/Contract Number:: AC07-05ID14517

OSTI ID:: 1823669

Alternate ID(s):: OSTI ID: 1833562

Report Number(s):: INL/JOU-21-62685-Rev000; S0306454921005880; 108712; PII: S0306454921005880

Journal Information:: Annals of Nuclear Energy, Journal Name: Annals of Nuclear Energy Vol. 166 Journal Issue: C; ISSN 0306-4549

Publisher:: ElsevierCopyright Statement

Country of Publication:: United Kingdom

Language:: English

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