Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography

A. W. Decker; N. J. Cherepy; S. Hok; C. J. McNamee; C. J. Delzer; P. A. Hausladen; J. P. Hayward

doi:10.1117/12.2595907

Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography

A. W. Decker, N. J. Cherepy, S. Hok, C. J. McNamee, C. J. Delzer, P. A. Hausladen, J. P. Hayward

Radiation Imaging and Advanced Diagnosti

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

Abstract

Plastic scintillators utilizing iridium complex fluorophores offer substantial improvements in light yield, and their light yield is not significantly quenched in compositions with bismuth metalorganic loading, at a loading level of 21 wt% bismuth metal. This new bismuth plastic (Ir-Bi-Plastic) offers improved detection efficiency over commercial plastic scintillators. One application for Ir-Bi-Plastic is in low-cost, portable, and durable dual-particle imaging (DPI) systems supporting nuclear safety, security, and safeguards. However, new materials must undergo investigation using industry standards to quantify their capabilities. In this work, an Ir-Bi-Plastic was experimentally evaluated as a small, pixelated radiographic array in a fast neutron environment, with individual pixel dimensions of 2×2×19 mm. For comparison, identical evaluations were conducted for two similarly sized arrays made from EJ-200 and EJ-256. A separate Ir-Bi-Plastic array with 5×5×20 mm pixels was also evaluated. ASTM methods were leveraged to determine the modulation transfer function and spatial resolution for each array. Edge response measurements of a 2-in thick tungsten block were recorded by pressure coupling all four arrays to a commercial a-Si digital radiographic panel. Experimental results were then compared for all four arrays, and the results demonstrated that the Ir-Bi-Plastic outperforms similar arrays made from EJ-200 and EJ-256 (5 wt% Pb). These findings suggest that DPI systems utilizing Ir-Bi-Plastic hold promise for continued development over older, more traditional, alternatives.

Original language	English
Title of host publication	Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII
Editors	Nerine J. Cherepy, Michael Fiederle, Ralph B. James
Publisher	SPIE
ISBN (Electronic)	9781510645141
DOIs	https://doi.org/10.1117/12.2595907
State	Published - 2021
Event	Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII 2021 - San Diego, United States Duration: Aug 1 2021 → Aug 5 2021

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	11838
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII 2021
Country/Territory	United States
City	San Diego
Period	08/1/21 → 08/5/21

Funding

The authors would like to thank the U.S. Army and the Department of Energy, including award DE-NA0003180 and DE-NA0000979, for supporting this NSSC affiliated research. The authors also thank Dr. Dan Shedlock and Varex Imaging for the use of a Varex Industrial PaxScan® 1515DXT-I flat panel detector, and Dr. Keith Vaigneur at Agile Technologies for his assistance and supervision in the fabrication of the evaluated arrays. This work was supported by the US DOE NA-22 DNN, and the LLNL portion was performed under the auspices of the U.S. Department of Energy by LLNL under Contract DE-AC52-07NA27344.

Keywords

Dual-particle imaging
Neutron
Neutron radiography
Radiography

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10.1117/12.2595907

Cite this

Decker, A. W., Cherepy, N. J., Hok, S., McNamee, C. J., Delzer, C. J., Hausladen, P. A., & Hayward, J. P. (2021). Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography. In N. J. Cherepy, M. Fiederle, & R. B. James (Eds.), Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII Article 118380A (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11838). SPIE. https://doi.org/10.1117/12.2595907

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title = "Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography",

abstract = "Plastic scintillators utilizing iridium complex fluorophores offer substantial improvements in light yield, and their light yield is not significantly quenched in compositions with bismuth metalorganic loading, at a loading level of 21 wt% bismuth metal. This new bismuth plastic (Ir-Bi-Plastic) offers improved detection efficiency over commercial plastic scintillators. One application for Ir-Bi-Plastic is in low-cost, portable, and durable dual-particle imaging (DPI) systems supporting nuclear safety, security, and safeguards. However, new materials must undergo investigation using industry standards to quantify their capabilities. In this work, an Ir-Bi-Plastic was experimentally evaluated as a small, pixelated radiographic array in a fast neutron environment, with individual pixel dimensions of 2×2×19 mm. For comparison, identical evaluations were conducted for two similarly sized arrays made from EJ-200 and EJ-256. A separate Ir-Bi-Plastic array with 5×5×20 mm pixels was also evaluated. ASTM methods were leveraged to determine the modulation transfer function and spatial resolution for each array. Edge response measurements of a 2-in thick tungsten block were recorded by pressure coupling all four arrays to a commercial a-Si digital radiographic panel. Experimental results were then compared for all four arrays, and the results demonstrated that the Ir-Bi-Plastic outperforms similar arrays made from EJ-200 and EJ-256 (5 wt% Pb). These findings suggest that DPI systems utilizing Ir-Bi-Plastic hold promise for continued development over older, more traditional, alternatives.",

keywords = "Dual-particle imaging, Neutron, Neutron radiography, Radiography",

author = "Decker, {A. W.} and Cherepy, {N. J.} and S. Hok and McNamee, {C. J.} and Delzer, {C. J.} and Hausladen, {P. A.} and Hayward, {J. P.}",

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doi = "10.1117/12.2595907",

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Decker, AW, Cherepy, NJ, Hok, S, McNamee, CJ, Delzer, CJ, Hausladen, PA & Hayward, JP 2021, Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography. in NJ Cherepy, M Fiederle & RB James (eds), Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII., 118380A, Proceedings of SPIE - The International Society for Optical Engineering, vol. 11838, SPIE, Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII 2021, San Diego, United States, 08/1/21. https://doi.org/10.1117/12.2595907

Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography. / Decker, A. W.; Cherepy, N. J.; Hok, S. et al.
Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII. ed. / Nerine J. Cherepy; Michael Fiederle; Ralph B. James. SPIE, 2021. 118380A (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 11838).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

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AU - Hok, S.

AU - McNamee, C. J.

AU - Delzer, C. J.

AU - Hausladen, P. A.

AU - Hayward, J. P.

N1 - Publisher Copyright: © COPYRIGHT SPIE.

PY - 2021

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N2 - Plastic scintillators utilizing iridium complex fluorophores offer substantial improvements in light yield, and their light yield is not significantly quenched in compositions with bismuth metalorganic loading, at a loading level of 21 wt% bismuth metal. This new bismuth plastic (Ir-Bi-Plastic) offers improved detection efficiency over commercial plastic scintillators. One application for Ir-Bi-Plastic is in low-cost, portable, and durable dual-particle imaging (DPI) systems supporting nuclear safety, security, and safeguards. However, new materials must undergo investigation using industry standards to quantify their capabilities. In this work, an Ir-Bi-Plastic was experimentally evaluated as a small, pixelated radiographic array in a fast neutron environment, with individual pixel dimensions of 2×2×19 mm. For comparison, identical evaluations were conducted for two similarly sized arrays made from EJ-200 and EJ-256. A separate Ir-Bi-Plastic array with 5×5×20 mm pixels was also evaluated. ASTM methods were leveraged to determine the modulation transfer function and spatial resolution for each array. Edge response measurements of a 2-in thick tungsten block were recorded by pressure coupling all four arrays to a commercial a-Si digital radiographic panel. Experimental results were then compared for all four arrays, and the results demonstrated that the Ir-Bi-Plastic outperforms similar arrays made from EJ-200 and EJ-256 (5 wt% Pb). These findings suggest that DPI systems utilizing Ir-Bi-Plastic hold promise for continued development over older, more traditional, alternatives.

AB - Plastic scintillators utilizing iridium complex fluorophores offer substantial improvements in light yield, and their light yield is not significantly quenched in compositions with bismuth metalorganic loading, at a loading level of 21 wt% bismuth metal. This new bismuth plastic (Ir-Bi-Plastic) offers improved detection efficiency over commercial plastic scintillators. One application for Ir-Bi-Plastic is in low-cost, portable, and durable dual-particle imaging (DPI) systems supporting nuclear safety, security, and safeguards. However, new materials must undergo investigation using industry standards to quantify their capabilities. In this work, an Ir-Bi-Plastic was experimentally evaluated as a small, pixelated radiographic array in a fast neutron environment, with individual pixel dimensions of 2×2×19 mm. For comparison, identical evaluations were conducted for two similarly sized arrays made from EJ-200 and EJ-256. A separate Ir-Bi-Plastic array with 5×5×20 mm pixels was also evaluated. ASTM methods were leveraged to determine the modulation transfer function and spatial resolution for each array. Edge response measurements of a 2-in thick tungsten block were recorded by pressure coupling all four arrays to a commercial a-Si digital radiographic panel. Experimental results were then compared for all four arrays, and the results demonstrated that the Ir-Bi-Plastic outperforms similar arrays made from EJ-200 and EJ-256 (5 wt% Pb). These findings suggest that DPI systems utilizing Ir-Bi-Plastic hold promise for continued development over older, more traditional, alternatives.

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Decker AW, Cherepy NJ, Hok S, McNamee CJ, Delzer CJ, Hausladen PA et al. Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography. In Cherepy NJ, Fiederle M, James RB, editors, Hard X-Ray, Gamma-Ray, and Neutron Detector Physics XXIII. SPIE. 2021. 118380A. (Proceedings of SPIE - The International Society for Optical Engineering). doi: 10.1117/12.2595907

Evaluation of novel bismuth-loaded plastic arrays for fast neutron radiography

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