H. R. Andrews scite author profile

A passive neutron-bubble dosemeter (BD), developed by Bubble Technology Industries, has been used for space applications. Both the bubble detector-personal neutron dosemeter and bubble detector spectrometer have been studied at ground-based facilities in order to characterise their response due to neutrons, heavy ion particles and protons. This technology was first used during the Canadian-Russian collaboration aboard the Russian satellite BION-9, and subsequently on other space missions, including later BION satellites, the space transportation system, Russian MIR space station and International Space Station. This paper provides an overview of the experiments that have been performed for both ground-based and space studies in an effort to characterise the response of these detectors to various particle types in low earth orbit and presents results from the various space investigations.

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Fast neutron measurements using Cs2LiYCl6:Ce (CLYC) scintillator

Smith¹,

Achtzehn²,

Andrews³

et al. 2015

Nuclear Instruments and Methods in Physics Research Section A:

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Measurements of the neutron dose and energy spectrum on the International Space Station during expeditions ISS-16 to ISS-21

Smith¹,

Akatov

Andrews³

et al. 2012

Radiation Protection Dosimetry

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As part of the international Matroshka-R and Radi-N experiments, bubble detectors have been used on board the ISS in order to characterise the neutron dose and the energy spectrum of neutrons. Experiments using bubble dosemeters inside a tissue-equivalent phantom were performed during the ISS-16, ISS-18 and ISS-19 expeditions. During the ISS-20 and ISS-21 missions, the bubble dosemeters were supplemented by a bubble-detector spectrometer, a set of six detectors that was used to determine the neutron energy spectrum at various locations inside the ISS. The temperature-compensated spectrometer set used is the first to be developed specifically for space applications and its development is described in this paper. Results of the dose measurements indicate that the dose received at two different depths inside the phantom is not significantly different, suggesting that bubble detectors worn by a person provide an accurate reading of the dose received inside the body. The energy spectra measured using the spectrometer are in good agreement with previous measurements and do not show a strong dependence on the precise location inside the station. To aid the understanding of the bubble-detector response to charged particles in the space environment, calculations have been performed using a Monte-Carlo code, together with data collected on the ISS. These calculations indicate that charged particles contribute <2% to the bubble count on the ISS, and can therefore be considered as negligible for bubble-detector measurements in space.

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H. R. Andrews

Fast Neutron Spectroscopy Using${\rm Cs}_{2}{\rm LiYCl}_{6}{:}{\rm Ce}$ (CLYC) Scintillator

Fast Neutron Detection With ${\rm Cs}_{2} {\rm LiYCl}_{6}$

Review of bubble detector response characteristics and results from space

Fast neutron measurements using Cs2LiYCl6:Ce (CLYC) scintillator

Measurements of the neutron dose and energy spectrum on the International Space Station during expeditions ISS-16 to ISS-21

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