Extension of the discrete generalized multigroup method using SPH factors

Richard L. Reed; Jeremy A. Roberts

doi:10.1016/j.anucene.2021.108832

Extension of the discrete generalized multigroup method using SPH factors

Richard L. Reed, Jeremy A. Roberts

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Abstract

The discrete generalized multigroup (DGM) method provides a way to treat the energy dependence of neutron transport similarly to the standard multigroup approximation. However, DGM uses an orthogonal basis to retain the energy dependence in higher-order terms. Using correction factors similar to traditional Superhomogénéisation (SPH) factors, the DGM method may be extended to produce cross sections that are homogenized over both space and energy. Since some fine-group energy dependence is retained, the resulting homogenized cross sections are more problem-independent than cross sections homogenized by SPH factors alone. In particular, a 44-group set of cross sections is collapsed to approximately a 1% error in the pincell fission densities for a test problem using three DOF per coarse energy group.

Original language	English
Article number	108832
Journal	Annals of Nuclear Energy
Volume	167
DOIs	https://doi.org/10.1016/j.anucene.2021.108832
State	Published - Mar 2022

Funding

The work of the first author was supported by the Kansas State University Nuclear Research Fellowship Program, generously sponsored by the US Nuclear Regulatory Commission (Grant NRC–HQ-84–14-G-0033).

Keywords

Discrete generalized multigroup
Proper orthogonal decomposition
Superhomogénéisation (SPH) factors

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10.1016/j.anucene.2021.108832

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title = "Extension of the discrete generalized multigroup method using SPH factors",

abstract = "The discrete generalized multigroup (DGM) method provides a way to treat the energy dependence of neutron transport similarly to the standard multigroup approximation. However, DGM uses an orthogonal basis to retain the energy dependence in higher-order terms. Using correction factors similar to traditional Superhomog{\'e}n{\'e}isation (SPH) factors, the DGM method may be extended to produce cross sections that are homogenized over both space and energy. Since some fine-group energy dependence is retained, the resulting homogenized cross sections are more problem-independent than cross sections homogenized by SPH factors alone. In particular, a 44-group set of cross sections is collapsed to approximately a 1% error in the pincell fission densities for a test problem using three DOF per coarse energy group.",

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AU - Roberts, Jeremy A.

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AB - The discrete generalized multigroup (DGM) method provides a way to treat the energy dependence of neutron transport similarly to the standard multigroup approximation. However, DGM uses an orthogonal basis to retain the energy dependence in higher-order terms. Using correction factors similar to traditional Superhomogénéisation (SPH) factors, the DGM method may be extended to produce cross sections that are homogenized over both space and energy. Since some fine-group energy dependence is retained, the resulting homogenized cross sections are more problem-independent than cross sections homogenized by SPH factors alone. In particular, a 44-group set of cross sections is collapsed to approximately a 1% error in the pincell fission densities for a test problem using three DOF per coarse energy group.

KW - Discrete generalized multigroup

KW - Proper orthogonal decomposition

KW - Superhomogénéisation (SPH) factors

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VL - 167

JO - Annals of Nuclear Energy

JF - Annals of Nuclear Energy

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Extension of the discrete generalized multigroup method using SPH factors

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