Development of a novel neutron detection technique by using a boron layer coating a Charge Coupled Device

Blostein, Juan Jerónimo; Estrada, Juan; Tartaglione, Aureliano; Sofo haro, Miguel; Fernández Moroni, Guillermo; Cancelo, Gustavo

doi:10.1088/1748-0221/10/01/P01006

Development of a novel neutron detection technique by using a boron layer coating a Charge Coupled Device

Juan Jerónimo Blostein
(
- Centro Atomico Bariloche and
- Buenos Aires, CONICET
)
,
Juan Estrada
(
- Fermilab
)
,
Aureliano Tartaglione
(
- Centro Atomico Bariloche and
- Buenos Aires, CONICET
)
,
Miguel Sofo haro
(
- Centro Atomico Bariloche and
- Buenos Aires, CONICET
)
,
Guillermo Fernández Moroni
(
- Bahia Blanca, U. Natl. Del Sur and
- Buenos Aires, CONICET
)

Aug 14, 2014

14 pages

Published in:

JINST 10 (2015) 01, P01006

Published: Jan 19, 2015

e-Print:

1408.3263 [physics.ins-det]

DOI:

10.1088/1748-0221/10/01/P01006

Report number:

FERMILAB-PUB-14-381

View in:

pdf

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Abstract: (IOP)

This article describes the design features and the first test measurements obtained during the installation of a novel high resolution 2D neutron detection technique. The technique proposed in this work consists of a boron layer (enriched in (10)B) placed on a scientific Charge Coupled Device (CCD). After the nuclear reaction (10)B(n,α)(7)Li, the CCD detects the emitted charge particles thus obtaining information on the neutron absorption position. The above-mentioned ionizing particles, with energies in the range 0.5–5.5 MeV, produce a plasma effect in the CCD which is recorded as a circular spot. This characteristic circular shape, as well as the relationship observed between the spot diameter and the charge collected, is used for the event recognition, allowing the discrimination of undesirable gamma events. We present the first results recently obtained with this technique, which has the potential to perform neutron tomography investigations with a spatial resolution better than that previously achieved. Numerical simulations indicate that the spatial resolution of this technique will be about 15 μm, and the intrinsic detection efficiency for thermal neutrons will be about 3%. We compare the proposed technique with other neutron detection techniques and analyze its advantages and disadvantages.

Neutron detectors (cold, thermal, fast neutrons)
Instrumentation for neutron sources
Inspection with neutrons
Beam-line instrumentation (beam position and profile monitors; beam- intensity monitors; bunch length monitors)

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