THERMOCOAX rhodium SPND sensitivity dispersion and validation of the sensitivity calculation model

This paper describes the neutron irradiation tests of 7 THERMOCOAX Self-Powered Neutron detectors (SPNDs) in the BR1 reactor at SCK•CEN. The SPNDs were fabricated according to the same specifications, but from different fabrication batches. The SPND signals were recorded during stepwise power-up of...

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Bibliographic Details
Published in:EPJ Web of conferences 2020, Vol.225, p.4015
Main Authors: Vermeeren, L., Leysen, W., Pichon, L., Salou, V., Helleux, G.
Format: Article
Language:English
Subjects:
Activation
Beta decay
Emitters
Gamma rays
Linearity
Mathematical models
modelling
Neutron counters
neutron detectors
Neutron flux
Neutron irradiation
Neutrons
Nuclear capture
nuclear measurements
pulse shape discrimination
reactor instrumentation
Rhodium
Sensitivity
Signal processing
Thermal neutrons
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Summary:This paper describes the neutron irradiation tests of 7 THERMOCOAX Self-Powered Neutron detectors (SPNDs) in the BR1 reactor at SCK•CEN. The SPNDs were fabricated according to the same specifications, but from different fabrication batches. The SPND signals were recorded during stepwise power-up of the reactor, proving the linearity of the SPND response within a wide thermal neutron flux range: from as low as 0.8·10 9 n/(cm 2 ) to 2.6·1011 n/(cm 2 s). Intercomparison of the SPND signals shows a very small spread, confirming the repeatability of the THERMOCOAX fabrication processes. The overall neutron sensitivities of the seven SPNDs agreed within a 1% margin. The experimental data were analyzed in terms of prompt and various delayed responses. Prompt contributions to the signal are due to external gamma induced processes and to processes involving gamma rays emitted instantaneously upon neutron capture. The main contribution in a rhodium SPND is due to activation of the rhodium emitter and beta emission during decay of the activated rhodium and leads to a delayed response with a characteristic time of a few minutes. Activation and subsequent beta decay in other materials present in the SPND lead to additional minor delayed signal contributions. The partial SPND sensitivities due to all these processes were calculated using an MCNPX based model and were compared with experimental sensitivities based on the recorded data. The results were in fair agreement; for the overall SPND neutron sensitivity an agreement within a 1% margin was achieved.
ISSN:2100-014X
2101-6275
2100-014X
DOI:10.1051/epjconf/202022504015