https://doi.org/10.1140/epjti/s40485-022-00086-x
Research Article
First evaluation of a novel ionisation chamber for thermal neutron beam monitoring
1
European Spallation Source ERIC, 22100, Lund, Sweden
2
Division of Nuclear Physics, Lund University, 223 63, Lund, Sweden
3
CERN, 1211, Geneva, Switzerland
4
University of Hamburg, 20146, Hamburg, Germany
5
CDT CASCADE Detector Technologies GmbH, 69123, Heidelberg, Germany
6
GSI Helmholtzzentrum für Schwerionenforschung GmbH, 64291, Darmstadt, Germany
7
Università degli Studi di Milano-Bicocca, 20126, Milano, Italy
8
University of Glasgow, G12 8Q, Glasgow, United Kingdom
9
Sensors and Devices Centre, Foundation Bruno Kessler, 38123, Trento, Italy
10
RISE, 1040, Vienna, Austria
Received:
28
March
2022
Accepted:
4
October
2022
Published online:
25
October
2022
The European Spallation Source ERIC (ESS), currently under construction in Lund, Sweden is a facility established to deliver the highest integrated neutron flux originating from a pulsed source with the aim of supporting an initial fifteen neutron instruments for cutting edge science experiments. This in turn requires reliable monitoring at complex neutron beam lines: in particular, linearity, timing capability, adaptability of the design for various flux ranges (dynamic range) and sensitivity to neutrons within the range of 0.6-10Å are expected from the neutron beam monitors to be installed at the ESS beam lines. Additionally, operational stability and low attenuation are also desirable characteristics for such neutron beam monitoring. A prototype neutron beam monitor based on the ionisation chamber principle and a boron converter, designed by CDT CASCADE Detector Technologies GmbH and ESS, has been investigated at the BER-II research reactor of Helmholtz Zentrum Berlin (HZB). The effort to design and investigate a thermal neutron ionisation beam monitor was initiated by adapting the concept of ionisation chambers previously known elsewhere. So far all the characterised neutron beam monitors discriminate neutron hits on a discrete event basis (pulse mode), whereas the beam monitor prototype introduced in this paper estimates the total flux as a function of current (current mode). While most other neutron beam monitoring devices and detectors rely upon a signal amplifying gain stage, the ionisation chamber operates without any gain and is consequently robust against typical detector ageing effects that compromise the sensitivity over time. The initial tests were performed at the ESS V20 test beam line under realistic conditions resembling those of the future pulses of ESS. The linearity is demonstrated for 3Å pulses in the flux range of 2-3 × 105 n/s/cm2 and for white pulses (0.6-10Å) in the range of 1-5 × 106 n/s/cm2. The timing behaviour resembles the data previously recorded at the V20 beam lines. This novel implementation of a neutron sensitive ionisation chamber shows great promise for beam monitoring and diagnostics at ESS. As the ionisation beam monitor itself is an entirely passive device, it is adequately robust to be employed in areas of high irradiation where no regular servicing or maintenance can be provided.
Key words: Ionisation chamber / Thermal neutron / Neutron monitor
© The Author(s) 2022
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