Development of a ceramic double thick GEM detector for transmission measurements at the VESUVIO instrument at ISIS

Neutron spallation sources always require new instrument upgrades and innovations in order to improve the quality of their experiments. In this framework, the capability to accurately measure total neutron cross sections at the VESUVIO instrument at the ISIS Facility can be boosted by a tailored tra...

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Bibliographic Details
Published in:Journal of instrumentation 2021-06, Vol.16 (6), p.P06003
Main Authors: Cancelli, S., Muraro, A., Perelli Cippo, E., Romanelli, G., Abba, A., Chen, Y., Grosso, G., Gorini, G., Hu, Z., Lai, C.-C., Mc Cormack, O., Robinson, L., Svensson, P.-O., Tardocchi, M., Hall-Wilton, R., Xie, Y., Zhijia, S., Zhou, J., Zhou, X., Croci, G.
Format: Article
Language:English
Subjects:
Ceramics
Condensed matter physics
Fast neutrons
Foils
Measuring instruments
Neutrons
Nuclear cross sections
Sensors
Spallation
Spatial resolution
Stability analysis
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Summary:Neutron spallation sources always require new instrument upgrades and innovations in order to improve the quality of their experiments. In this framework, the capability to accurately measure total neutron cross sections at the VESUVIO instrument at the ISIS Facility can be boosted by a tailored transmission detector. For this reason, the first double ceramic thick GEM detector has been realised. Detectors based on GEM technology are broadly developed thanks to their characteristics, such as good spatial resolution (< 0.5 mm), good detection efficiency, high rate capability (MHz/mm 2 ) and a possible coverage area of some meters at low costs. This article shows the realisation of a GEM detector made of a 10 B 4 C cathode, two ceramic thick GEM foils and a padded anode, as well as the device characterisation on the VESUVIO beam line, where stability, γ-sensitivity, imaging capability and sample analysis have been studied. The successful results confirm that the ceramic thick GEM detector performs well in thermal and epithermal neutron detection and it will allow the scientific user community of the instrument to perform better quality transmission measurements so as to determine more accurate total neutron cross section of condensed-matter systems.
ISSN:1748-0221
1748-0221
DOI:10.1088/1748-0221/16/06/P06003