Hart, Shane scite author profile

Hart, Shane

5Publications

10Citation Statements Received

37Citation Statements Given

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Affiliations

Oak Ridge National Laboratory, University of Tennessee at Knoxville, Nuclear Energy Agency

Publications

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Creation of problem-dependent Doppler-broadened cross sections in the KENO Monte Carlo code

Shane

Celik

Maldonado

et al. 2016

Annals of Nuclear Energy

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This paper introduces a quick method for improving the accuracy of Monte Carlo simulations by generating one-and twodimensional cross sections at a user-defined temperature before performing transport calculations. A finite difference method is used to Doppler-broaden cross sections to the desired temperature, and unit-base interpolation is done to generate the probability distributions for double differential two-dimensional thermal moderator cross sections at any arbitrarily user-defined temperature. The accuracy of these methods is tested using a variety of contrived problems. In addition, various benchmarks at elevated temperatures are modeled, and results are compared with benchmark results. The problem-dependent cross sections are observed to produce eigenvalue estimates that are closer to the benchmark results than those without the problem-dependent cross sections.

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Monte Carlo Capabilities of the SCALE Code System

Rearden

Petrie

Peplow

et al. 2014

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SCALE is a widely used suite of tools for nuclear systems modeling and simulation that provides comprehensive, verified and validated, user-friendly capabilities for criticality safety, reactor physics, radiation shielding, and sensitivity and uncertainty analysis. For more than 30 years, regulators, licensees, and research institutions around the world have used SCALE for nuclear safety analysis and design. SCALE provides a ''plug-and-play'' framework that includes three deterministic and three Monte Carlo radiation transport solvers that can be selected based on the desired solution, including hybrid deterministic/ Monte Carlo simulations. SCALE includes the latest nuclear data libraries for continuous-energy and multigroup radiation transport as well as activation, depletion, and decay calculations. SCALE's graphical user interfaces assist with accurate system modeling, visualization, and convenient access to desired results. SCALE 6.2 will provide several new capabilities and significant improvements in many existing features, especially with expanded continuous-energy Monte Carlo capabilities for criticality safety, shielding, depletion, and sensitivity and uncertainty analysis. An overview of the Monte Carlo capabilities of SCALE is provided here, with emphasis on new features for SCALE 6.2.

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Monte Carlo capabilities of the SCALE code system

Rearden

Petrie

Peplow

et al. 2015

Annals of Nuclear Energy

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a b s t r a c t SCALE is a widely used suite of tools for nuclear systems modeling and simulation that provides comprehensive, verified and validated, user-friendly capabilities for criticality safety, reactor physics, radiation shielding, and sensitivity and uncertainty analysis. For more than 30 years, regulators, licensees, and research institutions around the world have used SCALE for nuclear safety analysis and design. SCALE provides a ''plug-and-play'' framework that includes three deterministic and three Monte Carlo radiation transport solvers that can be selected based on the desired solution, including hybrid deterministic/ Monte Carlo simulations. SCALE includes the latest nuclear data libraries for continuous-energy and multigroup radiation transport as well as activation, depletion, and decay calculations. SCALE's graphical user interfaces assist with accurate system modeling, visualization, and convenient access to desired results. SCALE 6.2 will provide several new capabilities and significant improvements in many existing features, especially with expanded continuous-energy Monte Carlo capabilities for criticality safety, shielding, depletion, and sensitivity and uncertainty analysis. An overview of the Monte Carlo capabilities of SCALE is provided here, with emphasis on new features for SCALE 6.2.

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Implementation of the direct S(α,β) method in the KENO Monte Carlo code

Shane

Maldonado

2017

Annals of Nuclear Energy

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The Monte Carlo code KENO contains thermal scattering data for a wide variety of thermal moderators. These data are processed from Evaluated Nuclear Data Files (ENDF) by AMPX and stored as double differential probability distribution functions. The method examined in this paper uses S(α, β) probability distribution functions derived from the ENDF data files directly instead of being converted to double differential cross sections. This allows the size of the cross section data on the disk to be reduced substantially amount. KENO has also been updated to allow interpolation in temperature on these data so that problems can be run at any temperature. Results are shown for several simplified problems for a variety of moderators. In addition, benchmark models based on the KRITZ reactor in Sweden were run, and the results are compared with the previous versions of KENO without the Direct S(α, β) method. Results from the Direct S(α, β) method compare favorably with the original results obtained using the double differential cross sections. Sampling the data increases the run-time of the Monte Carlo calculation, but memory usage is decreased substantially.

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Improvements of SCALE Infrastructure on Microsoft Windows [Slides]

Shane

Johnson

Lefebvre

et al. 2023

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Hart, Shane

Creation of problem-dependent Doppler-broadened cross sections in the KENO Monte Carlo code

Monte Carlo Capabilities of the SCALE Code System

Monte Carlo capabilities of the SCALE code system

Implementation of the direct S(α,β) method in the KENO Monte Carlo code

Improvements of SCALE Infrastructure on Microsoft Windows [Slides]

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