Neutron Imaging at LANSCE—From Cold to Ultrafast

Nelson, R. O.; Vogel, Sven C.; Hunter, James F.; Watkins, Erik B.; Losko, Adrian S.; Tremsin, Anton S.; Borges, Nicholas; Cutler, Theresa; Dickman, L. Turin; Espy, Michelle A.; Gautier, D. C.; Madden, Amanda; Majewski, Jarosław; Malone, Michael W.; Mayo, Douglas R.; McClellan, Kenneth J.; Montgomery, David; Mosby, S.; Nelson, Andrew T.; Ramos, Kyle; Schirato, R.; Schroeder, Katlin; Sevanto, Sanna; Swift, Alicia L.; Vo, Long; Williamson, Thomas E.; Winch, Nicola M.

doi:10.3390/jimaging4020045

Cited by 41 publications

(18 citation statements)

References 71 publications

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“…This data was collected over a period of several days in December of 2018, in 3 segments (due to the part height and limited beam profile). The panel used was a Perkin-Elmer 1621 panel, with a pixel pitch of 200 microns, with an attached 2.5 mm thick PP + ZnS:Cu scintillator from RC Tritec (for additional details, refer to [ 8 ]). The scintillator was thick, a design choice made to improve detection efficiency, but at the expense of spatial resolution.…”

Section: Methodsmentioning

confidence: 99%

“…The neutron source was approximately 21 m from the part, and the panel was approximately 10 cm behind the part. The neutron beam was effectively collimated to 3 cm in the vertical direction and 7 cm in the horizontal direction, resulting in an

ratio of approximately 700 vertical and 300 horizontal [ 8 ]. Thus, we are able to use a parallel beam approximation in the reconstruction.…”

Section: Methodsmentioning

confidence: 99%

“…In 1972, the first commercial CT machine was developed by Sir Godfrey Hounsfield [ 4 ], and in the decades that followed, applications of computed tomography using X-rays have been the subject of intense study, both in the medical and industrial fields. In parallel, neutron radiography was developed in the 1930s [ 5 , 6 ] and has been used to successfully produce images of reasonable quality in the subsequent decades [ 7 , 8 ]. Additionally, parametric studies to understand image formation in neutron radiography have been performed (for fast neutrons, for example, see [ 9 ]).…”

Section: Introductionmentioning

confidence: 99%

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On a Method For Reconstructing Computed Tomography Datasets from an Unstable Source

et al. 2020

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As work continues in neutron computed tomography, at Los Alamos Neutron Science Center (LANSCE) and other locations, source reliability over the long imaging times is an issue of increasing importance. Moreover, given the time commitment involved in a single neutron image, it is impractical to simply discard a scan and restart in the event of beam instability. In order to mitigate the cost and time associated with these options, strategies are presented in the current work to produce a successful reconstruction of computed tomography data from an unstable source. The present work uses a high energy neutron tomography dataset from a simulated munition collected at LANSCE to demonstrate the method, which is general enough to be of use in conjunction with unstable X-ray computed tomography sources as well.

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Section: Methodsmentioning

confidence: 99%

ratio of approximately 700 vertical and 300 horizontal [ 8 ]. Thus, we are able to use a parallel beam approximation in the reconstruction.…”

Section: Methodsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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On a Method For Reconstructing Computed Tomography Datasets from an Unstable Source

et al. 2020

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“…For some applications, such as epithermal energy-resolved neutron imaging, allowing to measure isotope densities [10], the resolution available with a shorter flight path is acceptable. The concurrent flux increase from the 1/L 2 ratio of the LANSCE FP5/ERNI beamline [29], where these experiments are presently conducted at around 10 m sample to detector distance, would therefore enable some applications at neutron count times similar to what is required at LANSCE.…”

Section: Quantitative Comparison With the Lansce Pulsed Sourcesmentioning

confidence: 99%

Short-Pulse Laser-Driven Moderated Neutron Source

et al. 2020

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Neutron production with laser-driven neutron sources was demonstrated. We outline the basics of laser-driven neutron sources, highlight some fundamental advantages, and quantitatively compare the neutron production at the TRIDENT laser sources with the well-established LANSCE pulsed neutron spallation source. Ongoing efforts by our team to continue development of these sources, in particular the LANSCE-ina-box instrument, are described. The promise of ultra-intense lasers as drivers for brilliant, compact, and highly efficient particle accelerators portends driving next-generation neutron sources, potentially replacing in some cases much larger conventional accelerators.

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“…Neutron imaging is a powerful tool for characterizing engineering materials because they can penetrate thick specimens and provide a complimentary contrast to X-rays [1,2]. Driven by the recent advent of spallation (pulsed) neutron sources and the availability of time-of-flight imaging detectors [3], there has been an emergence of wavelengthresolved (WR)/time-of-flight (ToF) neutron imaging instruments [4][5][6][7]. While WR imaging instruments have been used for tomographic characterization of amorphous samples (for example [8]), using them to image samples with single-crystal This manuscript has been authored by UT-Battelle, LLC, under Contract No.…”

Section: Introductionmentioning

confidence: 99%

Wavelength-resolved Neutron Tomography for Crystalline Materials

Venkatakrishnan

Dessieux

Bingham

2019

ICASSP 2019 - 2019 IEEE International Conference on Acoustics, Speech and Signal Processing (ICASSP)

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Wavelength-resolved (WR) neutron transmission tomography is an emerging technique to characterize engineering materials. While tomographic reconstruction for amorphous samples is straightforward, it is challenging to reconstruct samples with single-crystal domains because the attenuation of the sample varies as a function of its orientation with respect to the incident beam due to Bragg scattering. In this paper, we present an algorithm that can reconstruct samples with single-crystal domains from WR neutron tomographic measurements. In particular, we use a model-based iterative reconstruction (MBIR) technique that reconstructs the volume by identifying and leaving out the regions of the measurement that are affected by Bragg scatter. We combine the output of the MBIR method with an algorithm that matches the reconstruction to the identified Bragg scatter to reconstruct a feature that corresponds to the local crystallography of the sample being measured. Using simulated data, we demonstrate how our algorithm can reconstruct materials with single-crystal domains, thereby adding a powerful new capability for WR neutron imaging instruments.

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Neutron Imaging at LANSCE—From Cold to Ultrafast

Cited by 41 publications

References 71 publications

On a Method For Reconstructing Computed Tomography Datasets from an Unstable Source

On a Method For Reconstructing Computed Tomography Datasets from an Unstable Source

Short-Pulse Laser-Driven Moderated Neutron Source

Wavelength-resolved Neutron Tomography for Crystalline Materials

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