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

Shane, Hart,; Celik, Cihangir; Maldonado, G. Ivan; Leal, L.C.

doi:10.1016/j.anucene.2015.10.011

Cited by 8 publications

(12 citation statements)

References 8 publications

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“…The Doppler Broadening Rejection Correction (DBRC) [4] was one of the early proposed techniques to treat the effect of strong variations of the interaction cross section within the energetic vicinity of a scattering neutron, whereas S(α, β) tables had been used prior [11]. The method has since been implemented in numerous continuous energy Monte Carlo neutron transport programs [4,39,35,18], and has shown to successfully model the resonance upscatter effect. However, DBRC suffers from rejection probabilities as high as 99.995% [31] for neutron energies in the vicinity of a resonance.…”

Section: Introductionmentioning

confidence: 99%

Resonance Scattering Treatment with the Windowed Multipole Formalism

Ridley¹,

Forget²,

Burke³

2023

Preprint

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A new method for directly sampling the resonance upscattering effect is presented. Alternatives have relied on inefficient rejection sampling techniques or large tabular storage of relative velocities. None of these approaches, which require pointwise energy data, are particularly well suited to the windowed multipole cross section representation. The new method called multipole analytic resonance scattering (MARS) overcomes these limitations by inverse transform sampling from the target relative velocity distribution where the cross section is expressed in the multipole formalism. The closed form relative speed distribution contains a novel special function we deem the incomplete Faddeeva function, and we present the first results on its efficient numerical evaluation.

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Section: Introductionmentioning

confidence: 99%

Resonance Scattering Treatment with the Windowed Multipole Formalism

Ridley¹,

Forget²,

Burke³

2023

Preprint

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“…Additionally, the computational performance and trade-offs in memory and run time for each of the methods are quantified. Four methods are compared: the traditional method of storing cross section data at a select few temperatures (the Library method), calculating all the interpolated cross sections in a 1D and a 2D space before radiation transport is simulated (the 1D Preprocess and 2D Preprocess methods) Hart et al 2016, and an on-the-fly method using a WMP technique (the WMP method) Josey et al 2016. These methods were used in three radiation transport problems, and the results were compared with respect to accuracy, run time, and memory usage.…”

Section: Introductionmentioning

confidence: 99%

Comparison of Temperature-Dependent Cross Section Treatments within the Shift Monte Carlo Radiation Transport Code

Bachmann,

Johnson,

Hart

et al. 2023

Preprint

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“…ENDF files provide the thermal moderating data at a fixed number of temperatures. In order to to obtain temperatures at intermediate values, an interpolation scheme 40 implemented using a unit-based interpolation scheme similiar to that described in (Hart et al, 2014). The S(α, β) data are only used for inelastic scattering.…”

Section: Introductionmentioning

confidence: 99%

“…To test the accuracy of the temperature intperolation, 295 benchmarks were chosen to be consistent with those in previous Doppler broadening work. (Hart et al, 2016)…”

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confidence: 99%

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

Cited by 8 publications

References 8 publications

Resonance Scattering Treatment with the Windowed Multipole Formalism

Resonance Scattering Treatment with the Windowed Multipole Formalism

Comparison of Temperature-Dependent Cross Section Treatments within the Shift Monte Carlo Radiation Transport Code

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

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