Characterization of the Core Face Irradiation Fixture at the Pennsylvania State University Breazeale Reactor

Susanna B. Angermeier; Maksat Kuatbek; Daniel Beck; Amanda M. Johnsen

doi:10.1016/j.nucengdes.2024.113483

Characterization of the Core Face Irradiation Fixture at the Pennsylvania State University Breazeale Reactor

Susanna B. Angermeier, Maksat Kuatbek, Daniel Beck, Amanda M. Johnsen

Ken and Mary Alice Lindquist Department of Nuclear Engineering

Research output: Contribution to journal › Article › peer-review

Abstract

An efficient stacking method was applied to a multi-foil activation characterization of a core face fixture in Penn State's TRIGA reactor using STAYSL PNNL software. The adjusted neutron energy spectra from the STAYSL PNNL software are in good agreement with the input MCNP models. The validated MCNP model was then used to predict the neutron energy spectrum within the core face fixture with a new lead shielding assembly in between the fixture and the core. Additional irradiation environment details such as the estimated gamma ray dose rates and sample temperatures provide a more comprehensive view of the core face fixture beyond the neutron energy spectrum, especially for more sensitive materials.

Original language	English (US)
Article number	113483
Journal	Nuclear Engineering and Design
Volume	428
DOIs	https://doi.org/10.1016/j.nucengdes.2024.113483
State	Published - Nov 2024

All Science Journal Classification (ASJC) codes

Nuclear and High Energy Physics
General Materials Science
Nuclear Energy and Engineering
Safety, Risk, Reliability and Quality
Waste Management and Disposal
Mechanical Engineering

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10.1016/j.nucengdes.2024.113483

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title = "Characterization of the Core Face Irradiation Fixture at the Pennsylvania State University Breazeale Reactor",

abstract = "An efficient stacking method was applied to a multi-foil activation characterization of a core face fixture in Penn State's TRIGA reactor using STAYSL PNNL software. The adjusted neutron energy spectra from the STAYSL PNNL software are in good agreement with the input MCNP models. The validated MCNP model was then used to predict the neutron energy spectrum within the core face fixture with a new lead shielding assembly in between the fixture and the core. Additional irradiation environment details such as the estimated gamma ray dose rates and sample temperatures provide a more comprehensive view of the core face fixture beyond the neutron energy spectrum, especially for more sensitive materials.",

author = "Angermeier, {Susanna B.} and Maksat Kuatbek and Daniel Beck and Johnsen, {Amanda M.}",

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language = "English (US)",

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AU - Angermeier, Susanna B.

AU - Kuatbek, Maksat

AU - Beck, Daniel

AU - Johnsen, Amanda M.

PY - 2024/11

Y1 - 2024/11

N2 - An efficient stacking method was applied to a multi-foil activation characterization of a core face fixture in Penn State's TRIGA reactor using STAYSL PNNL software. The adjusted neutron energy spectra from the STAYSL PNNL software are in good agreement with the input MCNP models. The validated MCNP model was then used to predict the neutron energy spectrum within the core face fixture with a new lead shielding assembly in between the fixture and the core. Additional irradiation environment details such as the estimated gamma ray dose rates and sample temperatures provide a more comprehensive view of the core face fixture beyond the neutron energy spectrum, especially for more sensitive materials.

AB - An efficient stacking method was applied to a multi-foil activation characterization of a core face fixture in Penn State's TRIGA reactor using STAYSL PNNL software. The adjusted neutron energy spectra from the STAYSL PNNL software are in good agreement with the input MCNP models. The validated MCNP model was then used to predict the neutron energy spectrum within the core face fixture with a new lead shielding assembly in between the fixture and the core. Additional irradiation environment details such as the estimated gamma ray dose rates and sample temperatures provide a more comprehensive view of the core face fixture beyond the neutron energy spectrum, especially for more sensitive materials.

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VL - 428

JO - Nuclear Engineering and Design

JF - Nuclear Engineering and Design

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ER -

Characterization of the Core Face Irradiation Fixture at the Pennsylvania State University Breazeale Reactor

Abstract

All Science Journal Classification (ASJC) codes

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