MPACT Fast Neutron Multiplicity System Design Concepts

Chichester, David L.; Pozzi, Sara A.; Dolan, Jennifer L.; Kinlaw, Mathew T.; Kaplan, A. C.; Flaska, Marek; Enqvist, Andreas; Johnsom, J. T.; Watson, Scott M.

doi:10.2172/1057209

Cited by 9 publications

(6 citation statements)

References 8 publications

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“…The idea for using the time-correlation for non-destructive inspection of objects containing fissile material has been pursued for "passive" interrogation schemes [21,22,24,[26][27][28][29][30][49][50][51][52] (where the natural background initiates the fission chains) and for "active" interrogation schemes [19,20,23,25,53] (where a beam of particles induces the fission chains).…”

Section: Time-correlation Of Fission-chain Neutronsmentioning

confidence: 99%

“…All of these methods use single-particle signals. Multi-particle schemes, usually two-and three-neutron signals have also been pursued, with photon [19,20] and neutron [21][22][23][24][25] beams as well as in passive interrogation [26][27][28][29][30][31][32], where ambient radiations are used to induce the signals. Here we report on an active interrogation method using 9 MeV Bremsstrahlung photons to induce the emission of time-correlated, prompt neutrons measured within the Prompt Neutrons from Photofission (PNPF) system developed at Passport Systems Inc. (PSI) [33][34][35].…”

Section: Introductionmentioning

confidence: 99%

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Fissile material detection using neutron time-correlations from photofission

et al. 2019

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The detection of special nuclear materials (SNM) in commercial cargoes is a major objective in the field of nuclear security. In this work we investigate the use of two-neutron time-correlations from photo-fission using the Prompt Neutrons from Photofission (PNPF) detectors in Passport Systems Inc.'s (PSI) Shielded Nuclear Alarm Resolution (SNAR) platform for the purpose of detecting ∼5 kg quantities of fissionable materials in seconds. The goal of this effort was to extend the secondary scan mode of this system to differentiate fissile materials, such as highly enriched uranium, from fissionable materials, such as low enriched and depleted uranium (LEU and DU). Experiments were performed using a variety of material samples, and data were analyzed using the variance-over-mean technique referred to as Y2F or Feynman-α. Results were compared to computational models to improve our ability to predict system performance for distinguishing fissile materials. Simulations were then combined with empirical formulas to generate receiver operating characteristics (ROC) curves for a variety of shielding scenarios. We show that a 10 second screening with a 200 µA 9 MeV X-ray beam is sufficient to differentiate kilogram quantities of HEU from DU in various shielding scenarios in a standard cargo container. * soltz1@llnl.gov

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Section: Time-correlation Of Fission-chain Neutronsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Fissile material detection using neutron time-correlations from photofission

et al. 2019

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“…PuFirst order factor of spontaneous fission; vsf,2-240 Pu Second order factorial moments of spontaneous fission; vsf,3-240 Pu Third order factorial moments of spontaneous fission; vi1-239 Pu The First Order Factor of Induced Fission; vi2-239 Pu the second order factor of the fission multiplicity; vi3-239 Pu triggering the third order factor of fission multiplicity; fddouble counting rate (Doubles) gate width factor; ft-triple count factor (Triples) of the door width factor; scattering crosstalk rate; ε-detection efficiency. After solving M, the values of F and α are solved by the equation 5and (6)…”

Section: Quantum Description Of Fast Neutron Multiplicitymentioning

confidence: 99%

“…In order to maintain good detection efficiency, only through quantitative simulation to get accurate results. The model of the measurement device used in the simulation study (the scintillator position shown in Fig.3) was established by reference to the model in reference [6]. The geometric layout of the measuring device is a 3×8, uniformly wound ∅5 "x 2" BC-501-A liquid scintillator detector with a detector surface distance of 20 cm from the center axis.…”

Section: Simulation Studymentioning

confidence: 99%

Computer Simulation of Fast Neutron Multiplicity Analysis

Zhuang¹,

Zhang²,

Zuo³

et al. 2017

Proceedings of the 2017 6th International Conference on Energy, Environment and Sustainable Development (ICEESD 2017)

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The paper constructs the model of nuclear materials and fast neutron multiplicity counter, and obtains the mass of nuclear materials by utilizing the equation of fast neutron multiplicity. Via GEANT4 tool kit, the paper obtains the simulated results which are identical well to the results calculated by the equation. This indicates the validity and feasibility of computer simulation of fast neutron multiplicity analytical method and lays the foundation of the design and application of fast neutron multiplicity counter.

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“…[3,4,5] This work, supported by the U.S. Department of Energy's Fuel Cycle Research and Development program and its Materials Protection, Accounting, and Control Technologies (MPACT) program, has been a collaborative effort including staff at INL as well as staff and students in the Department of Nuclear Engineering & Radiological Sciences at the University of Michigan (UM). These activities have included simulation and modeling using the MCNPX-PoliMi Monte Carlo simulation tool and experiments to validate the simulations, development of hands-on experimental methods, and the discovery of pitfalls and challenges in performing these types of measurements that cannot be identified any other way.…”

Section: Introductionmentioning

confidence: 99%

MPACT Fast Neutron Multiplicity System Prototype Development

Chichester¹,

Pozzi²,

Dolan³

et al. 2013

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This document serves as both an FY2103 End-of-Year and End-of-Project report on efforts that resulted in the design of a prototype fast neutron multiplicity counter leveraged upon the findings of previous project efforts. The prototype design includes 32 liquid scintillator detectors with cubic volumes 7.62 cm in dimension configured into 4 stacked rings of 8 detectors. Detector signal collection for the system is handled with a pair of Struck Innovative Systeme 16-channel digitizers controlled by in-house developed software with built-in multiplicity analysis algorithms. Initial testing and familiarization of the currently obtained prototype components is underway, however full prototype construction is required for further optimization.Monte Carlo models of the prototype system were performed to estimate die-away and efficiency values. Analysis of these models resulted in the development of a software package capable of determining the effects of nearest-neighbor rejection methods for elimination of detector cross talk. A parameter study was performed using previously developed analytical methods for the estimation of assay mass variance for use as a figure-of-merit for system performance. [1, 2] A software package was developed to automate these calculations and ensure accuracy. The results of the parameter study show that the prototype fast neutron multiplicity counter design is very nearly optimized under the restraints of the parameter space.

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MPACT Fast Neutron Multiplicity System Design Concepts

Cited by 9 publications

References 8 publications

Fissile material detection using neutron time-correlations from photofission

Fissile material detection using neutron time-correlations from photofission

Computer Simulation of Fast Neutron Multiplicity Analysis

MPACT Fast Neutron Multiplicity System Prototype Development

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