Your search keyword '"Alexander B Laptev"' showing total 30 results

1. Fast Neutron–Induced Fission Cross Sections of 233, 234, 236, 238U up to 200 MeV

Author

Fredrik Tovesson, Tony S. Hill, and Alexander B Laptev

Subjects

Nuclear physics, Physics, Nuclear Energy and Engineering, Fission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Physics::Accelerator Physics, Neutron, Nuclear Experiment

Abstract

The 233, 234, 236, 238U fission cross sections have been measured relative to 235U(n, f) for incident neutron energies from 200 KeV to 200 MeV using neutron time-of-flight at the Los Alamos...

Published

2014

2. A new neutron counter for fission research

Author

B. Laurent, J. Taieb, Fredrik Tovesson, G. Belier, A. Chatillon, J. F. Martin, J.M. O׳Donnell, F.-J. Hambsch, T. Granier, R. O. Nelson, Alexander B Laptev, and R. C. Haight

Subjects

inorganic chemicals, Physics, Nuclear and High Energy Physics, integumentary system, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, technology, industry, and agriculture, Fast fission, Neutron temperature, Nuclear physics, Prompt neutron, biological sciences, Neutron cross section, Neutron source, lipids (amino acids, peptides, and proteins), Neutron, Nuclear Experiment, Instrumentation, Delayed neutron

Abstract

A new neutron counter for research experiments on nuclear fission has been developed. This instrument is designed for the detection of prompt fission neutrons within relatively high levels of gamma and neutron background. It is composed of a set of 3He proportional counters arranged within a block of polyethylene which serves as moderator. The detection properties have been studied by means of Monte Carlo simulations and experiments with radioactive sources. These properties are confirmed by an experiment on neutron-induced fission of 238U at the WNR facility of the Los Alamos Neutron Science Center during which the mean prompt fission neutron multiplicity, or ν ¯ has been measured from 1 to 20 MeV of incident neutron energy.

Published

2014

3. The Prompt Fission Neutron Spectrum (PFNS) Measurement Program at LANSCE

Author

J. L. Ullmann, A. Chyzh, J. M. Gostic, R. C. Haight, Roger Henderson, E. Kwan, Todd Bredeweg, Terry N. Taddeucci, Ching-Yen Wu, Alexander B Laptev, Morgan C. White, Matthew Devlin, R. O. Nelson, John M. O'Donnell, Hye Young Lee, Marian Jandel, Nikolaos Fotiades, Stephen A. Wender, and B.A. Perdue

Subjects

Physics, Nuclear and High Energy Physics, Range (particle radiation), Fission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Nuclear data, Neutron temperature, Nuclear physics, Criticality, Prompt neutron, Neutron, Fission neutron, Nuclear Experiment

Abstract

The prompt neutron spectrum from neutron-induced fission needs to be known in designing new fast reactors, predicting criticality for safety analyses, and developing techniques for global security application. A program to measure this spectrum for neutron-induced fission of 239 Pu is underway at the Los Alamos Neutron Science Center. The goal is to obtain data on the shape of the spectrum with a small uncertainty over the emitted neutron energy range of 100 keV to 12 MeV with additional data below and above this range. The incident neutron energy range will be from 0.5 to 30 MeV. The status of this program including results of initial experimental measurements is described here.

Published

2014

4. Commissioning the NIFFTE Time Projection Chamber: Towards the 238U / 235U (n, f) Cross-section Ratio

Author

Dwayne Towell, S. M. Grimes, Tony S. Hill, T. N. Massey, R. S. Towell, G. Tatishvili, R. Meharchand, J. L. Klay, R. T. Thornton, D. Isenhower, B. Wendt, S. Watson, Sean C. Stave, L. Snyder, J. Bundgaard, Eric Burgett, H. Qu, M. Cunningham, B. Seilhan, D. M. Asner, D. L. Duke, Samuele Sangiorgio, J. Ruz, W. Loveland, N. Kornilov, Uwe Greife, R. G. Baker, Lynn Wood, J. Deaven, M. Heffner, Alexander B Laptev, V. Kleinrath, and Fredrik Tovesson

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Cross section (physics), Time projection chamber, Fission, Nuclear data, Neutron, Tracking (particle physics), Performance results

Abstract

The Neutron Induced Fission Fragment Tracking Experiment (NIFFTE) collaboration is developing a Time Projection Chamber (TPC) to measure neutron-induced fission cross sections with unprecedented accuracy. Modifying TPC technology for nuclear physics applications is a challenging endeavor, and frequent testing and evaluation is required to ensure that all components are behaving as expected. In-beam tests of the NIFFTE TPC at the Los Alamos Neutron Science Center (LAN-SCE) commenced in 2010. An overview of the NIFFTE TPC experiments performed at LANSCE will be presented, along with preliminary performance results.

Published

2014

5. Prompt Fission γ-rays Measured Using Liquid Scintillators

Author

J. L. Ullmann, Marian Jandel, Todd Bredeweg, Alexander B Laptev, Nikolaos Fotiades, B.A. Perdue, R. C. Haight, Terry N. Taddeucci, John M. O'Donnell, Hye Young Lee, A. Chyzh, Roger Henderson, E. Kwan, Stephen A. Wender, Ching-Yen Wu, R. O. Nelson, J. M. Gostic, and Matthew Devlin

Subjects

Physics, Nuclear and High Energy Physics, Fission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Nuclear data, Scintillator, Parallel plate, Neutron temperature, Coincidence, Spectral line, Nuclear physics, Nuclear Experiment, Spontaneous fission

Abstract

The prompt γ-ray spectra from 235U(n,f) at incident energies of 1 to 20 MeV and for 235Cf(s.f.) were measured up to 4 MeV in coincidence with two parallel plate avalanche counters and the liquid scintillator array FIGARO. The unfolded γ-ray spectra from 1–4 MeV using the single value decomposition and iterative Bayesian techniques for the incident neutron energy regions corresponding to the first, second and third chance fissions were found to nearly identical and similar to the distribution from the spontaneous fission of 252Cf. General agreement with the γ-ray distributions from fission was also found with previous measurements.

Published

2014

6. Development of Neutron Detector Arrays for Neutron-Induced Reaction Measurements

Author

Nikolaos Fotiadis, Morgan C. White, R. O. Nelson, J. L. Ullmann, J. M. Gostic, Hye Young Lee, Roger Henderson, B.A. Perdue, Terry N. Taddeucci, R. C. Haight, Marian Jandel, Matthew Devlin, E. Kwan, A. Chyzh, Stephen A. Wender, Ching-Yen Wu, Todd Bredeweg, Alexander B Laptev, and John M. O'Donnell

Subjects

Bonner sphere, Physics, Nuclear and High Energy Physics, Neutron transport, Nuclear Theory, Neutron scattering, Neutron temperature, Nuclear physics, Nuclear Energy and Engineering, Neutron cross section, Neutron source, Neutron detection, Neutron, Electrical and Electronic Engineering, Nuclear Experiment

Abstract

The outgoing neutron energy spectra from neutron-induced fission of various actinides are important for basic understanding of the fission process near the scission point as well as playing a large role in neutron transport codes, which are heavily relied upon in the design of advanced nuclear reactors and simulations of critical assemblies. The reliability of the results of neutron transport models is a strong function of the quality of the nuclear data used as input. Currently, the world's experimental database of fission neutron spectra is severely incomplete (especially for higher incident neutron energies) with large uncertainties in key portions of the outgoing energy spectra. Many transport codes use evaluated data libraries, which are based on the approach of the Los Alamos model. Other theoretical models have been developed, but the available data cannot distinguish the results of different models (as is the case for 239Pu). Better measurements are needed for all incident and outgoing neutron energies, but most urgently in the low-energy (below 1 MeV) and high-energy (above 6 MeV) portions of the outgoing spectra where theoretical model results differ greatly. We present the design considerations (and some characterization results) of the two Chi-Nu neutron detector arrays: one array of 6Li-glass detectors and one array of liquid-scintillator detectors. These detector arrays are being constructed to meet the challenge of measuring the prompt fission neutron spectra (for a few common actinides) to a higher accuracy and precision than achieved previously and over a larger incident energy range than has been covered by previous experimenters. We see a significant reduction in neutron-scattering backgrounds with our new array designs.

Published

2013

7. Li-glass detector response study with a 252Cf source for low-energy prompt fission neutrons

Author

Terry N. Taddeucci, B.A. Perdue, Matthew Devlin, E. Kwan, A. Chyzh, Roger Henderson, Nikolaos Fotiades, Stephen A. Wender, Ching-Yen Wu, J. M. Gostic, Hye Young Lee, Marian Jandel, Todd Bredeweg, Alexander B Laptev, John M. O'Donnell, R. C. Haight, Morgan C. White, and R. O. Nelson

Subjects

Nuclear reaction, Physics, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, Fission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Monte Carlo method, Nuclear data, Particle detector, Nuclear physics, Neutron detection, Neutron, Nuclear Experiment, Instrumentation, Spontaneous fission

Abstract

Prompt-fission-neutron spectra for neutron-induced fission reactions on uranium and plutonium isotopes are important for nuclear applications. We have used 6 Li-glass scintillation detectors to measure outgoing neutron energies in the range from 10 keV to 1 MeV, where there is currently large uncertainty in nuclear data. To better understand the response of 6 Li-glass detectors in this energy range, measurements of well-known spontaneous-fission neutrons from a 252 Cf source were done in the neutron-beam flight path. Results were compared with Monte Carlo simulations and they show good agreement. Similar measurements with a 7 Li-glass detector were used to assess gamma-ray background yields.

Published

2013

8. Fission-fragment total kinetic energy and mass yields for neutron-induced fission of 235U and 238U with En =200 keV – 30 MeV

Author

D. Shields, F.-J. Hambsch, D.A. Mayorov, D. L. Duke, D. Richman, Fredrik Tovesson, K. Meierbachtol, V. Geppert-Kleinrath, R. Meharchand, Alexander B Laptev, Brett Manning, T. Brys, Shea Mosby, B. Perdue, and Marzio Vidali

Subjects

Physics, 010308 nuclear & particles physics, Fission, Astrophysics::High Energy Astrophysical Phenomena, QC1-999, Nuclear Theory, Nuclear data, Kinetic energy, 01 natural sciences, Nuclear physics, 0103 physical sciences, Ionization chamber, Neutron, Atomic physics, 010306 general physics, Nuclear Experiment

Abstract

The average Total Kinetic Energy (TKE ) release and fission-fragment yields in neutron-induced fission of 235 U and 238 U was measured using a Frisch-gridded ionization chamber. These observables are important nuclear data quantites that are relevant to applications and for informing the next generation of fission models. The measurements were performed a the Los Alamos Neutron Science Center and cover E n = 200 keV – 30 MeV. The double-energy (2E) method was used to determine the fission-fragment yields and two methods of correcting for prompt-neutron emission were explored. The results of this study are correlated mass and TKE data.

Published

2017

9. Fission-fragment properties in U238(n,f) between 1 and 30 MeV

Author

Alexander B Laptev, Marzio Vidali, Shea Mosby, F.-J. Hambsch, T. Bryś, D. L. Duke, and Fredrik Tovesson

Subjects

Physics, Range (particle radiation), 010308 nuclear & particles physics, Fission, Nuclear Theory, Center (category theory), Radioactive waste, Kinetic energy, 01 natural sciences, Nuclear physics, 0103 physical sciences, Neutron, Nuclear Experiment, 010306 general physics, Excitation, Energy (signal processing)

Abstract

The fragment mass and kinetic energy in neutron-induced fission of $^{238}\mathrm{U}$ has been measured for incident energies from 1 to 30 MeV at the Los Alamos Neutron Science Center. The change in mass distributions over this energy range were studied, and the transition from highly asymmetric to more symmetric mass distributions is observed. A decrease in average total kinetic energy $(\overline{\mathrm{TKE}})$ with increasing excitation energy is observed, consistent with previous experimental work. Additional structure at multichance fission thresholds is present in the $\overline{\mathrm{TKE}}$ data. The correlations between fragment masses and total kinetic energy and how that changes with excitation energy of the fissioning compound nucleus were also measured. The fission mass yields and average total kinetic energy are important for fission-based technologies such as nuclear reactors to understand nuclear waste generation and energy output when developing new and advanced concepts. The correlations between fragment mass and kinetic energy are needed both as input for theoretical calculations of the deexcitation process in fission fragments by prompt radiation emission and for validating advanced theoretical fission models describing the formation of the primordial fragments.

Published

2016

10. Prompt energy distribution of 235U(n,f) at bombarding energies of 1–20MeV

Author

R. C. Haight, Ching-Yen Wu, Roger Henderson, J. M. Gostic, Todd Bredeweg, Alexander B Laptev, B.A. Perdue, Matthew Devlin, John M. O'Donnell, Nikolaos Fotiades, Marian Jandel, Hye Young Lee, Terry N. Taddeucci, E. Kwan, A. Chyzh, R. O. Nelson, Stephen A. Wender, and J. L. Ullmann

Subjects

Nuclear reaction, Physics, Nuclear and High Energy Physics, Cold fission, Cluster decay, Fission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Nuclear physics, Uranium-235, Neutron, Nuclear Experiment, Instrumentation, Delayed neutron, Spontaneous fission

Abstract

The distributions of prompt γ rays from the spontaneous fission of 252Cf and neutron-induced fission of 235U were measured up to ∼ 4 MeV using a liquid scintillator array. The unfolding of measured fission γ rays is presented using the Single Value Decomposition and iterative Bayesian methods. General agreement was found with comparisons made with previous measurements. The energy dependence of the prompt γ - ray distributions for the spontaneous fission of 252Cf and the neutron-induced fission of 235U from bombarding energies of 1-2, 5-10, and 10–20 MeV were found to be almost identical in the γ - ray energy region 1–4 MeV.

Published

2012

11. Fission Cross Section Measurements of Actinides at LANSCE

Author

Alexander B Laptev, Fredrik Tovesson, and Tony S. Hill

Subjects

Physics, Nuclear physics, Cross section (physics), Fission, Ionization, Center (category theory), General Physics and Astronomy, Neutron, Actinide, Energy (signal processing)

Abstract

Fission cross sections of a range of actinides have been measured at the Los Alamos Neutron Science Center (LANSCE) in support of nuclear energy applications. By combining measurement at two LANSCE facilities, Lujan Center and the Weapons Neutron Research center (WNR), differential cross sections can be measured from sub-thermal energies up to 200 MeV. Incident neutron energies are determined using the time-of-flight method, and parallel-plate ionization chambers are used to measure fission cross sections relative to the {sup 235}U standard. Recent measurements include the {sup 233,238}U, {sup 239,242}Pu and {sup 243}Am neutron-induced fission cross sections. In this paper preliminary results for cross section data of {sup 243}Am and {sup 233}U will be presented.

Published

2011

12. The Recent Absolute Total np and pp Cross Section Determinations: Quality of Data Description and Prediction of Experimental Observables

Author

I. I. Strakovsky, W. J. Briscoe, Mark W. Paris, Ron L. Workman, Alexander B Laptev, Richard A. Arndt, and Robert C. Haight

Subjects

Nuclear physics, Physics, Scattering cross-section, Cross section (physics), Quality (physics), Scattering, General Physics and Astronomy, Experimental data, Observable, Data description

Abstract

The absolute total cross sections for np and pp scattering below 1000 MeV are determined based on partial-wave analyses (PWAs) of nucleon-nucleon scattering data. These cross sections are compared with the most recent ENDF/B-VII.0 and JENDL-3.3 data files, and the Nijmegen PWA. Systematic deviations from the ENDF/B-VII.0 and JENDL-3.3 evaluations are found to exist in the low-energy region. Comparison of the np evaluation with the result of most recent np total and differential cross section measurements will be discussed. Results of those measurements were not used in the evaluation database. A comparison was done to check a quality of evaluation and its capabilities to predict experimental observables. Excellent agreement was found between the new experimental data and our PWA predictions.

Published

2011

13. Measuring the α/SF Branching Ratio of 252Cf with the NIFFTE TPC

Author

S. Watson, M. Cunningham, W. Loveland, N. Kornilov, Samuele Sangiorgio, S. M. Grimes, D. L. Duke, R. G. Baker, Eric Burgett, Alexander B Laptev, J. L. Klay, Lynn Wood, Fredrik Tovesson, M. Heffner, D. M. Asner, G. Tatishvili, D. Isenhower, J. Bundgaard, J. Ruz, V. Kleinrath, J. Deaven, T. N. Massey, Uwe Greife, L. Snyder, Dwayne Towell, Sean C. Stave, B. Seilhan, R. Meharchand, B. Wendt, R. S. Towell, R. T. Thornton, Tony S. Hill, and H. Qu

Subjects

Physics, Nuclear and High Energy Physics, Physics::Instrumentation and Detectors, Branching fraction, Fission, Nuclear Theory, Nuclear data, Actinide, Tracking (particle physics), Charged particle, Nuclear physics, Neutron, Nuclear Experiment, Spontaneous fission

Abstract

A fission TPC is being developed to measure the energy-dependent neutron induced fission cross sections of the major and minor actinides to an accuracy of better than 1%. Achieving such an accuracy will depend in part, on the ability of the TPC to provide precise tracking and identification of charged particles. A measurement of the α -decay to spontaneous fission branching ratio of 252 Cf used to benchmark the performance of the TPC will be discussed.

Published

2014

14. Precision Velocity Measurements of Fission Fragments Using the SPIDER Detector

Author

Todd Bredeweg, Alexander B Laptev, Fredrik Tovesson, C.W. Arnold, Morgan C. White, R. O. Nelson, Marian Jandel, and K. Meierbachtol

Subjects

Nuclear physics, Nuclear and High Energy Physics, Materials science, Spectrometer, Physics::Instrumentation and Detectors, Fission, Detector, Resolution (electron density), Nuclear data, Decay chain, Nuclear Experiment, Charged particle, Ion

Abstract

The SPectrometer for Ion DEtermination in fission Research (SPIDER) measures both position and time-of-flight (TOF) of charged particles using a system of thin carbon foils, electrostatic mirrors, microchannel plates, delay-line anodes, and a fast TDC. Tests have been conducted using 229Th and the alpha emitters in its decay chain. To date, timing resolution of 200 ps (FWHM) has been achieved corresponding to roughly 0.5% uncertainty in velocity measurements of fission fragments over a flight path of 52.1 cm. This velocity resolution, in combination with demonstrated fragment energy resolution is sufficient for 1 amu resolution of light mass fragments.

Published

2014

15. The Data Analysis Framework for the NIFFTE Fission Time Projection Chamber

Author

L. Snyder, Sean C. Stave, Dwayne Towell, R. Meharchand, H. Qu, B. Seilhan, B. Wendt, T. N. Massey, W. Loveland, N. Kornilov, R. G. Baker, Tony S. Hill, V. Kleinrath, Lynn Wood, G. Tatishvili, Eric Burgett, S. M. Grimes, Samuele Sangiorgio, Fredrik Tovesson, J. Bundgaard, J. L. Klay, R. T. Thornton, R. S. Towell, M. Heffner, S. Watson, M. Cunningham, D. Isenhower, D. L. Duke, Alexander B Laptev, J. Deaven, J. Ruz, Uwe Greife, and D. M. Asner

Subjects

Nuclear physics, Nuclear and High Energy Physics, Time projection chamber, Traverse, Computer science, Fission, Nuclear data, Analysis software, Tracking (particle physics)

Abstract

The NIFFTE collaboration has developed a time projection chamber to study neutron-induced fission events in actinide targets by tracking and identifying fission fragments in three dimensions as they traverse a gas volume. This paper will provide an overview of the analysis software that has been developed by the NIFFTE collaboration, as well as examples of its success in analyzing data.

Published

2014

16. Development of an Ionization Chamber for the SPIDER Fission Fragment Detector

Author

Morgan C. White, R. O. Nelson, Todd Bredeweg, Alexander B Laptev, Marian Jandel, K. Meierbachtol, C.W. Arnold, and Fredrik Tovesson

Subjects

Nuclear and High Energy Physics, Spider, Energy loss, Materials science, Physics::Instrumentation and Detectors, Fragment (computer graphics), Fission, Nuclear Theory, Detector, Nuclear data, Kinetic energy, Nuclear physics, Ionization chamber, Physics::Atomic and Molecular Clusters, Atomic physics, Nuclear Experiment

Abstract

The ionization chamber component of the SPIDER detector has been designed to measure energy loss and kinetic energy of fragments produced through neutron-induced fission with energy resolutions of

Published

2014

17. An Ethernet-based Data Acquisition System for the NIFFTE Time Projection Chamber

Author

S. Watson, J. Deaven, D. M. Asner, G. Tatishvili, M. Cunningham, Eric Burgett, J. Ruz, Alexander B Laptev, T. N. Massey, W. Loveland, N. Kornilov, Uwe Greife, S. M. Grimes, R. G. Baker, M. Heffner, L. Snyder, Samuele Sangiorgio, J. L. Klay, H. Qu, Fredrik Tovesson, Sean C. Stave, B. Seilhan, Lynn Wood, V. Kleinrath, B. Wendt, R. T. Thornton, Dwayne Towell, Tony S. Hill, R. S. Towell, R. Meharchand, D. L. Duke, D. Isenhower, and J. Bundgaard

Subjects

Ethernet, Flexibility (engineering), Nuclear and High Energy Physics, Time projection chamber, business.industry, Computer science, Preamplifier, Nuclear physics, Data acquisition, Application-specific integrated circuit, Field-programmable gate array, business, Computer hardware, Communication channel

Abstract

When fully instrumented, the NIFFTE Time Projection Chamber will consist of nearly 6000 channels, each of which requires a preamplifier, ADC, and digital readout. To minimize channel cost and size, the EtherDAQ data acquisition system utilizes off-the-shelf FPGA and Ethernet fiber technology. This application of commercially-available components made it possible to meet the requirements of the DAQ system with considerably less development cost and time than the a customized ASIC solution, and provides considerable flexibility in the final design. The detailed design and current status of the preamplifier and EtherDAQ boards will be discussed.

Published

2014

18. Targets for Precision Measurements

Author

Eric Burgett, Alexander B Laptev, J. Bundgaard, S. Watson, J. L. Klay, J. Deaven, Fredrik Tovesson, R. T. Thornton, M. Cunningham, B. Selhan, H. Qu, M. Heffner, Tony S. Hill, D. M. Asner, Uwe Greife, D. Isenhower, R. S. Towell, W. Loveland, N. Kornilov, Samuele Sangiorgio, G. Tatishvili, R. G. Baker, Lynn Wood, D. L. Duke, J. Ruz, Thomas N. Massey, L. Yao, V. Kleinrath, L. Snyder, B. Wendt, Dwayne Towell, Steven M. Grimes, Sean C. Stave, and R. Meharchand

Subjects

Nuclear and High Energy Physics, Physics - Instrumentation and Detectors, Materials science, Fission, FOS: Physical sciences, Nuclear data, Instrumentation and Detectors (physics.ins-det), Actinide, Term (time), Nuclear physics, Irradiation, Nuclear Experiment (nucl-ex), Nuclear Experiment, Energy (signal processing)

Abstract

The general properties needed in targets (sources) for high precision, high accuracy measurements are reviewed. The application of these principles to the problem of developing targets for the Fission TPC is described. Longer term issues, such as the availability of actinide materials, improved knowledge of energy losses and straggling and the stability of targets during irradiation are also discussed.

Published

2014

19. SPIDER: A new instrument for fission fragment research at the Los Alamos Neutron Science Center

Author

L. Snyder, C.W. Arnold, A. A. Hecht, Rick Blakeley, Fredrik Tovesson, Morgan C. White, K. Meierbachtol, Drew Michael Mader, and Alexander B Laptev

Subjects

Spectrometer, Chemistry, Fission, Physics, QC1-999, Nuclear Theory, Bragg peak, Kinetic energy, Mass spectrometry, Fast fission, Neutron temperature, Nuclear physics, Neutron, Nuclear Experiment

Abstract

The study of fission fragment yields and how they behave as a function of excitation energy provides insight into the process in which they are formed. Fission yields are also important for nuclear applications, as they can be used as a diagnostic tool. A new instrument, SPIDER (Spectrometer for Ion DEtermination in fission Research), is being developed for measuring fission yields as a function of incident neutron energy at the Los Alamos Neutron Science Center. The instrument employs a time-of-flight mass spectrometry method in which the velocity and kinetic energy of the fragments are measured in order to determine their mass. Additionally, by using Bragg peak spectroscopy, the charge of the fragments can be identified. A prototype instrument has been developed and preliminary results indicate that ∼ 1 mass unit resolution is feasible using this approach. A larger detector array is currently being designed, and will be used at study fission yields from thermal neutron energies up to at least 20 MeV.

Published

2013

20. SPIDER: A NEW INSTRUMENT FOR FISSION YIELD MEASUREMENTS

Author

D. Shields, C.W. Arnold, Arnold J. Sierk, Rick Blakeley, Marian Jandel, K. Meierbachtol, Uwe Greife, L. Snyder, Todd Bredeweg, Alexander B Laptev, A. A. Hecht, Fredrik Tovesson, Morgan C. White, Drew Michael Mader, and B. Moore

Subjects

Nuclear physics, Physics, Spider, Nuclear engineering, Fission product yield

Published

2013

21. A HIGH RESOLUTION IONIZATION CHAMBER FOR THE SPIDER FISSION FRAGMENT DETECTOR

Author

Todd Bredeweg, Drew Michael Mader, Alexander B Laptev, C.W. Arnold, Morgan C. White, Marian Jandel, K. Meierbachtol, Fredrik Tovesson, R. O. Nelson, and A. A. Hecht

Subjects

Spider, Materials science, Optics, Fission, Fragment (computer graphics), business.industry, Ionization chamber, Resolution (electron density), Detector, business

Published

2013

22. PROMPT FISSION NEUTRON SPECTRUM STUDY AT LANSCE: CHI-NU PROJECT

Author

Roger Henderson, T. A. Bredeweg, R. O. Nelson, Alexander B Laptev, B.A. Perdue, E. Kwan, A. Chyzh, J. L. Ullmann, Hye Young Lee, J. M. O'Donnell, Terry N. Taddeucci, Morgan C. White, M. Jandel, Ching-Yen Wu, Matthew Devlin, Robert C. Haight, S. A. Wender, and Nikolaos Fotiades

Subjects

Nuclear physics, Physics, Fission neutron, Spectrum (topology)

Published

2013

23. Simplification of an MCNP model designed for dose rate estimation

Author

R.T. Perry and Alexander B Laptev

Subjects

Photon, Glovebox, Computer science, Physics, QC1-999, Dose estimation, Electromagnetic shielding, Neutron, Dose rate, Simulation

Abstract

A study was made to investigate the methods of building a simplified MCNP model for radiological dose estimation. The research was done using an example of a complicated glovebox with extra shielding. The paper presents several different calculations for neutron and photon dose evaluations where glovebox elements were consecutively excluded from the MCNP model. The analysis indicated that to obtain a fast and reasonable estimation of dose, the model should be realistic in details that are close to the tally. Other details may be omitted.

Published

2017

24. A high resolutuion ionization chamber for the SPIDER fission fragment detector

Author

Drew Michael Mader, C.W. Arnold, Morgan C. White, Ronald O. Nelson, Marian Jandel, K. Meierbachtol, A. A. Hecht, Todd Bredeweg, Alexander B Laptev, and Fredrik K. Tovesson

Subjects

Nuclear physics, Physics, Spider, Fragment (computer graphics), Fission, Ionization chamber, Detector

Published

2013

25. The NIFFTE project

Author

B. Wendt, J. Deaven, D. M. Asner, V. Kleinrath, Samuele Sangiorgio, J. Ruz, Tony S. Hill, Fredrik Tovesson, R. S. Towell, Uwe Greife, G. Tatishvili, Lynn Wood, L. Snyder, W. Loveland, N. Kornilov, Alexander B Laptev, Sean C. Stave, R. G. Baker, R. T. Thornton, B. Seilhan, Thomas N. Massey, H. Qu, S. Watson, M. Cunningham, M. Heffner, Eric Burgett, J. L. Klay, Dwayne Towell, Steven M. Grimes, R. Meharchand, D. L. Duke, D. Isenhower, and J. Bundgaard

Subjects

Physics, Time projection chamber, Physics - Instrumentation and Detectors, Fission, Fission chamber, Physics::Instrumentation and Detectors, Nuclear Theory, FOS: Physical sciences, MicroMegas detector, Instrumentation and Detectors (physics.ins-det), Tracking (particle physics), Nuclear physics, Gaseous detectors, Neutron, Nuclear Experiment (nucl-ex), Nuclear Experiment, Instrumentation, Reference standards, Mathematical Physics

Abstract

The Neutron Induced Fission Fragment Tracking Experiment (NIFFTE) is a double-sided Time Projection Chamber (TPC) with micromegas readout designed to measure the energy-dependent neutron-induced fission cross sections of the major and minor actinides with unprecedented accuracy. The NIFFTE project addresses the challenge of minimizing major sources of systematic uncertainties from previous fission chamber measurements such as: target and beam non-uniformities, misidentification of alpha and light charged particles as fission fragments, and uncertainties inherent to the reference standards used. In-beam tests of the NIFFTE TPC at the Los Alamos Neutron Science Center (LANSCE) started in 2010 and have continued in 2011, 2012 and 2013. An overview of the NIFFTE TPC status and performance at LANSCE will be presented., Comment: Prepared for JINST as proceeding of the MPGD13 Conference

Published

2013

26. LDRD Review of SPIDER: Position and Time-of-Flight Measurements

Author

Alexander B Laptev, K. Meierbachtol, C.W. Arnold, Morgan C. White, and Fredrik K. Tovesson

Subjects

Nuclear physics, Time of flight, Spider, Position (vector), Chemistry

Published

2012

27. TPC measurement support

Author

K. Meierbachtol, Alexander B Laptev, Fredrik K. Tovesson, and R. Meharchand

Subjects

Physics, Nuclear physics, Nuclear engineering

Published

2012

28. Progress in the Measurement of Prompt Neutron Output in Neutron-Induced Fission of 239Pu: The Chi-Nu Project

Author

Roger Henderson, Ching-Yen Wu, A. Chyzh, E. Kwan, Nikolaos Fotiadis, Todd Bredeweg, Alexander B Laptev, J. M. Gostic, Hye Young Lee, Morgan C. White, Matthew Devlin, Stephen A. Wender, Marian Jandel, B.A. Perdue, Terry N. Taddeucci, John M. O'Donnell, Robert C. Haight, J. L. Ullmann, and Ronald O. Nelson

Subjects

Nuclear physics, Physics, Prompt neutron, Fission, Nuclear engineering, Neutron

Published

2012

29. Development of an Array of Liquid Scintillators to Measure the Prompt Fission Neutron Spectrum at LANSCE

Author

Ching-Yen Wu, E. Kwan, Matthew Devlin, Hye Young Lee, A. Chyzh, J. M. Gostic, Marian Jandel, Terry N. Taddeucci, J. L. Ullmann, B.A. Perdue, Nikolaos Fotiades, Roger Henderson, Todd Bredeweg, Alexander B Laptev, John M. O'Donnell, Stephen A. Wender, R. C. Haight, and R. O. Nelson

Subjects

Bonner sphere, Physics, Nuclear and High Energy Physics, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Neutron temperature, Neutron time-of-flight scattering, Nuclear physics, Prompt neutron, Neutron cross section, Neutron detection, Neutron source, Neutron, Nuclear Experiment

Abstract

Higher quality measurements of outgoing prompt neutron spectra from neutron-induced fission as a function of the incoming neutron energy are needed. These data can be used in designing new fast reactors, predicting criticality for safety analyses, and developing techniques for global security applications. As part of the program to measure the prompt fission neutron spectra (PFNS) from the fission of 239 Pu at the Los Alamos Neutron Science Center, we are developing a new array of liquid-scintillator detectors. This array will be used to measure the PFNS over a range of outgoing neutron energies from approximately 600 keV to 12 MeV and incident neutron energies from 0.5 to 30 MeV. A complete characterization of the detectors and the array as a whole will be carried out, targeted at understanding the light-output curves, efficiencies, and the neutron multiple-scattering backgrounds.

Published

2014

30. Two detector arrays for fast neutrons at LANSCE

Author

Roger Henderson, R. C. Haight, Matthew Devlin, Stephen A. Wender, Morgan C. White, R. O. Nelson, Todd Bredeweg, Nikolaos Fotiades, Alexander B Laptev, Hye Young Lee, J. M. Gostic, E. Kwan, A. Chyzh, B.A. Perdue, Marian Jandel, John M. O'Donnell, Ching-Yen Wu, Terry N. Taddeucci, and J. L. Ullmann

Subjects

Physics, Bonner sphere, Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Fast fission, Neutron temperature, Nuclear physics, Neutron flux, Neutron cross section, Neutron detection, Neutron source, Neutron, Nuclear Experiment, Instrumentation, Mathematical Physics

Abstract

The neutron spectrum from neutron-induced fission needs to be known in designing new fast reactors, predicting criticality for safety analyses, and developing techniques for global security application. The experimental data base of fission neutron spectra is very incomplete and most present evaluated libraries are based on the approach of the Los Alamos Model. To validate these models and to provide improved data for applications, a program is underway to measure the fission neutron spectrum for a wide range of incident neutron energies using the spallation source of fast neutrons at the Weapons Neutron Research (WNR) facility at the Los Alamos Neutron Science Center (LANSCE). In a double time-of-flight experiment, fission neutrons are detected by arrays of neutron detectors to increase the solid angle and also to investigate possible angular dependence of the fission neutrons. The challenge is to measure the spectrum from low energies, down to 100 keV or so, to energies over 10 MeV, where the evaporation-like spectrum decreases by 3 orders of magnitude from its peak around 1 MeV. For these measurements, we are developing two arrays of neutron detectors, one based on liquid organic scintillators and the other on 6Li-glass detectors. The range of fission neutrons detected by organic liquid scintillators extends from about 600 keV to well over 10 MeV, with the lower limit being defined by the limit of pulse-shape discrimination. The 6Li-glass detectors have a range from very low energies to about 1 MeV, where their efficiency then becomes small. Various considerations and tests are in progress to understand important contributing factors in designing these two arrays and they include selection and characterization of photomultiplier tubes (PM), the performance of relatively thin (1.8 cm) 6Li-glass scintillators on 12.5 cm diameter PM tubes, use of 17.5 cm diameter liquid scintillators with 12.5 cm PM tubes, measurements of detector efficiencies with tagged neutrons from the WNR/LANSCE neutron beam, and efficiency calibration with 252Cf spontaneous fission neutrons. Design considerations and test results are presented.

Published

2012