In this advanced instructional laboratory, students explore complex detection systems and nondestructive assay techniques used in the field of nuclear physics. After setting up and calibrating a neutron detection system, students carry out timing and energy deposition analyses of radiation signals. Through the timing of prompt fission neutron signals, multiplicity counting is used to carry out a special nuclear material (SNM) nondestructive assay. Our experimental setup is comprised of eight trans-stilbene organic scintillation detectors in a well-counter configuration, and measurements are taken on a spontaneous fission source as well as two (α,n) sources. By comparing each source's measured multiplicity distribution, the resulting measurements of the (α,n) sources can be distinguished from that of the spontaneous fission source. Such comparisons prevent the spoofing, i.e., intentional imitation, of a fission source by an (α,n) neutron source. This instructional laboratory is designed for nuclear engineering and physics students interested in organic scintillators, neutron sources, and nonproliferation radiation measurement techniques.
Darby, Flynn B., et al. "Multiplicity counting using organic scintillators to distinguish neutron sources: An advanced teaching laboratory." American Journal of Physics, vol. 91, no. 11, Nov. 2023. https://doi.org/10.1119/5.0139531
Darby, Flynn B., Hua, Michael Y., Pakari, Oskari V., Clarke, Shaun D., & Pozzi, Sara A. (2023). Multiplicity counting using organic scintillators to distinguish neutron sources: An advanced teaching laboratory. American Journal of Physics, 91(11). https://doi.org/10.1119/5.0139531
Darby, Flynn B., Hua, Michael Y., Pakari, Oskari V., et al., "Multiplicity counting using organic scintillators to distinguish neutron sources: An advanced teaching laboratory," American Journal of Physics 91, no. 11 (2023), https://doi.org/10.1119/5.0139531
@article{osti_2561493,
author = {Darby, Flynn B. and Hua, Michael Y. and Pakari, Oskari V. and Clarke, Shaun D. and Pozzi, Sara A.},
title = {Multiplicity counting using organic scintillators to distinguish neutron sources: An advanced teaching laboratory},
annote = {In this advanced instructional laboratory, students explore complex detection systems and nondestructive assay techniques used in the field of nuclear physics. After setting up and calibrating a neutron detection system, students carry out timing and energy deposition analyses of radiation signals. Through the timing of prompt fission neutron signals, multiplicity counting is used to carry out a special nuclear material (SNM) nondestructive assay. Our experimental setup is comprised of eight trans-stilbene organic scintillation detectors in a well-counter configuration, and measurements are taken on a spontaneous fission source as well as two (α,n) sources. By comparing each source's measured multiplicity distribution, the resulting measurements of the (α,n) sources can be distinguished from that of the spontaneous fission source. Such comparisons prevent the spoofing, i.e., intentional imitation, of a fission source by an (α,n) neutron source. This instructional laboratory is designed for nuclear engineering and physics students interested in organic scintillators, neutron sources, and nonproliferation radiation measurement techniques.},
doi = {10.1119/5.0139531},
url = {https://www.osti.gov/biblio/2561493},
journal = {American Journal of Physics},
issn = {ISSN 0002-9505},
number = {11},
volume = {91},
place = {United States},
publisher = {American Association of Physics Teachers (AAPT)},
year = {2023},
month = {11}}
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