Development of a Compact Flat Response Neutron Detector

Harano, Hideki; Matsumoto, Tadao; Nishiyama, Jun; Masuda, Akihiko; Uritani, Akira; Kudo, K.

doi:10.1109/tns.2011.2163191

Cited by 8 publications

(2 citation statements)

References 16 publications

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“…In this study, the ratio was 0.911, which is in reasonably good agreement with previously reported values [8]. Additional measurements using a flat-response detector [9] are also planned. …”

Section: Fluence Measurementsupporting

confidence: 91%

Development of a neutron standard field using a heavy-water moderated 252Cf source at NMIJ-AIST

Masuda¹,

Harano²,

Matsumoto³

et al. 2014

Progress in Nuclear Science and Technology

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A neutron standard field using a heavy-water moderated 252 Cf source has been developed at the National Metrology Institute of Japan, National Institute of Advanced Industrial Science and Technology. It can produce an energy distribution consisting of a remaining spontaneous fission spectrum and a slowing-down continuum to the low-energy region, which is similar to that present in real workplaces at nuclear facilities. The heavy-water moderated 252 Cf source and irradiation system includes shadow cones for measurements of scattered neutrons, and was designed using Monte-Carlo simulations based on the MCNPX code. The field was characterized using detector measurements and the results were compared to calculations. A fluence measurement was performed using a 6" Bonner sphere detector and the result agreed with the calculation to within the experimental uncertainty. In addition, a spectral measurement was carried out using a Bonner sphere spectrometer and the unfolding method and the unfolded spectrum was found to be in good agreement with the calculated spectrum.

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Section: Fluence Measurementsupporting

confidence: 91%

Development of a neutron standard field using a heavy-water moderated 252Cf source at NMIJ-AIST

Masuda¹,

Harano²,

Matsumoto³

et al. 2014

Progress in Nuclear Science and Technology

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“…It could not satisfy the Chinese Standard HJ 1157-2021 [18], which stated that the relative response deviation should be between -30% and 30% in the energy range of 50-3000 keV. The use of multiple probes to optimize the response of the detector has been studied in the field of long neutron counter, and good results have been obtained, which provided an idea for solving the problem of uneven response of 𝑋/𝛾 dose rate meters [19][20][21].…”

Section: Introductionmentioning

confidence: 99%

Research on multi-probe energy response compensation for X/γ dose rate meter

Li,

Gong,

Zhang

et al. 2024

J. Inst.

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Dose rate meters operating in pulse counting mode usually encounter the problem of uneven energy response. While current methods of coating a single probe with a metal layer can effectively improve the flatness of the energy response, the energy range of the flat response is limited. In this research, a multi-probe energy response compensation method was proposed to solve the problem of uneven energy response of a CsI(Tl) dose rate meter. In this method, different relative energy response curves were obtained by adding different hardware compensations to a probe. Then, two to four relative energy response curves were selected and weighted to obtain a flatter response within the energy region of interest. Specifically, first, 51 compensation schemes were obtained by changing the geometry and material parameters of the CsI(Tl) probe compensation layer. Second, the relative energy response curves of CsI(Tl) probes with 51 compensation schemes were obtained by MCNP simulation. Finally, the weight coefficient of each relative energy response curve was determined by overdetermined equations, and the combination with the smallest relative energy response deviation was selected. Within the energy range of 80–1500 keV, the optimal two-probe compensation scheme was selected from one to three probe compensation schemes. After the dual probe combination compensation, the relative energy response deviation ranged from -23.0% to 5.0%. Within the energy range of 50–3000 keV, the compensation schemes of one to four probes were traversed. The optimal three-probe compensation schemes were selected. After combined compensation, the relative energy response deviation ranged from -27.3% to 15.3%. Furthermore, the compensation effect of multiple probes was better than that of single probes in both energy regions of interest. Simulation results demonstrated that our proposed method can significantly improve the flatness of the energy response of dose rate meters based on CsI(Tl).

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Gas ionization detectors

Steinhäuser¹,

Buchtela²

2020

Handbook of Radioactivity Analysis

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Development of a Compact Flat Response Neutron Detector

Cited by 8 publications

References 16 publications

Development of a neutron standard field using a heavy-water moderated 252Cf source at NMIJ-AIST

Development of a neutron standard field using a heavy-water moderated 252Cf source at NMIJ-AIST

Research on multi-probe energy response compensation for X/γ dose rate meter

Gas ionization detectors

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