Your search keyword '"Brett Manning"' showing total 26 results

1. Measurement of material isotopics and atom number ratio with α-particle spectroscopy for a NIFFTE fission Time Projection Chamber actinide target

Author

J. A. Magee, C. A. Hagmann, Fredrik Tovesson, C. Prokop, B. Seilhan, W. Loveland, Denise Neudecker, A. Kemnitz, Daniel James Higgins, Mateusz Monterial, Nikolaos Fotiades, D. Cebra, D. Hensle, M. Heffner, L. Yao, L. D. Isenhower, N. Walsh, T.S. Watson, Samuele Sangiorgio, Kyle Schmitt, J. Gearhart, M. P. Mendenhall, R. S. Towell, Brett Manning, Jonathan B. King, Nathaniel Bowden, T. Classen, Uwe Greife, Shea Mosby, E. Leal-Cidoncha, J. L. Klay, J. Bundgaard, L. Snyder, Walid Younes, Robert Casperson, V. Geppert-Kleinrath, D.H. Dongwi, Kareem Kazkaz, Joseph Latta, and M. Anastasiou

Subjects

Physics, Nuclear and High Energy Physics, Time projection chamber, Isotope, Fission, Analytical chemistry, Atomic number, Actinide, Nuclear Experiment, Mass spectrometry, Spectroscopy, Instrumentation, Spectral line

Abstract

We present the results of a measurement of isotopic concentrations and atomic number ratio of a double-sided actinide target using α -spectroscopy and mass spectrometry. The double-sided actinide target, with predominantly 239Pu on one side and 235U on the other, was used in the fission Time Projection Chamber (fissionTPC) for a measurement of the neutron-induced fission cross-section ratio between the two isotopes. The measured atomic number ratio is needed to extract an absolute measurement fission cross-section ratio. The 239Pu/235U atom number ratio was measured with a combination of mass spectrometry and α -spectroscopy with a planar silicon detector achieving uncertainties of less than 1%. Different strategies for estimating isotopic concentration from the α -spectrum are presented to demonstrate the potential of these methods for non-destructive target assay. We found that a combination of fitting spectra with constraints from mass spectrometry, and summing counts in a region of the spectrum provided the most consistent results with the lowest uncertainty.

Published

2022

2. Fission fragment mass yields and total kinetic energy release in neutron-induced fission of U233 from thermal energies to 40 MeV

Author

D.A. Mayorov, Fredrik Tovesson, Shea Mosby, Uwe Greife, Kyle Schmitt, Brett Manning, and Daniel James Higgins

Subjects

Physics, Isotope, 010308 nuclear & particles physics, Fission, Nuclear Theory, Center (category theory), Kinetic energy, 01 natural sciences, Thorium fuel cycle, Nuclear physics, Momentum, Prompt neutron, 0103 physical sciences, Neutron, Nuclear Experiment, 010306 general physics

Abstract

Properties of fission in $^{233}\mathrm{U}$ were measured at the Los Alamos Neutron Science Center at incident neutron energies from thermal to 40 MeV. Fragments were observed in coincidence by using a twin ionization chamber with Frisch grids. The average total kinetic energy released and fragment mass yields were determined by using the double energy analysis method based on conservation of mass and momentum. The experimental method was validated by using $^{232}\mathrm{Th}$ and absolute energy was calibrated by using thermal-neutron--induced fission of $^{235}\mathrm{U}$. This work incorporates novel applications of multi-chance fission channel cross sections and fission models to account for the complexities introduced by prompt neutron emission at high energy and extends results up to higher incident neutron energies than previously measured. Accurate experimental measurements of these parameters are necessary to better understand the fission process in isotopes central to the thorium fuel cycle.

Published

2020

3. Neutron Induced Fission Fragment Angular Distributions, Anisotropy, and Linear Momentum Transfer Measured with the NIFFTE Fission Time Projection Chamber

Author

Jonathan B. King, D. Higgins, T. R. Towell, Z. Q. Case, J. L. Klay, T. Classen, A. Kemnitz, C. L. Towell, D. L. Duke, L. Yao, E. Leal, E. Guardincerri, N. Fotiadis, M. Heffner, Samuele Sangiorgio, G. Oman, N. Walsh, L. Snyder, C. A. Hagmann, K. Kazkaz, M. P. Mendenhall, Christopher Prokop, V. Geppert-Kleinrath, K. J. Kiesling, Joseph Latta, T.S. Watson, Brett Manning, K. J. Brewster, Nathaniel Bowden, R. S. Towell, D. Hensle, M. Monterial, M. Lynch, J. A. Magee, B. Seilhan, J. T. Barker, J. S. Barrett, C. R. Hicks, Shea Mosby, W. Loveland, Walid Younes, Uwe Greife, J. Bundgaard, Robert Casperson, D. Cebra, Fredrik Tovesson, L. D. Isenhower, Kyle Schmitt, and J. Gearhart

Subjects

Physics, Range (particle radiation), Time projection chamber, 010308 nuclear & particles physics, Fission, Nuclear Theory, FOS: Physical sciences, Observable, Tracking (particle physics), 01 natural sciences, Nuclear physics, Cross section (physics), 0103 physical sciences, Physics::Atomic and Molecular Clusters, Neutron, Nuclear Experiment (nucl-ex), 010306 general physics, Anisotropy, Nuclear Experiment

Abstract

The Neutron Induced Fission Fragment Tracking Experiment (NIFFTE) collaboration has performed measurements with a fission time projection chamber (fissionTPC) to study the fission process by reconstructing full three-dimensional tracks of fission fragments and other ionizing radiation. The amount of linear momentum imparted to the fissioning nucleus by the incident neutron can be inferred by measuring the opening angle between the fission fragments. Using this measured linear momentum, fission fragment angular distributions can be converted to the center-of-mass frame for anisotropy measurements. Angular anisotropy is an important experimental observable for understanding the quantum mechanical state of the fissioning nucleus and vital to determining detection efficiency for cross section measurements. Neutron linear momentum transfer to fissioning $^{235}$U, $^{238}$U, and $^{239}$Pu and fission fragment angular anisotropy of $^{235}$U and $^{238}$U as a function of neutron energies in the range 130 keV--250 MeV are presented.

Published

2020

4. Fission fragment angular anisotropy in neutron-induced fission of U235 measured with a time projection chamber

Author

Nathaniel Bowden, Fredrik Tovesson, J. A. Magee, V. Geppert-Kleinrath, Jonathan B. King, D. Hensle, H. Leeb, J. L. Klay, L. Snyder, Uwe Greife, L. D. Isenhower, D. L. Duke, A. C. Tate, R. S. Towell, Kyle Schmitt, J. Gearhart, Samuele Sangiorgio, N. Walsh, C. A. Hagmann, M. P. Mendenhall, D. Higgins, W. Loveland, J. Ruz, Walid Younes, D. Cebra, E. Guardincerri, Brett Manning, T. Classen, M. Heffner, Robert Casperson, S. Watson, L. Yao, M. Cunningham, J. S. Barrett, J. Bundgaard, and B. Seilhan

Subjects

Physics, Cluster decay, Time projection chamber, 010308 nuclear & particles physics, Fission, Nuclear Theory, Nuclear data, Tracking (particle physics), 01 natural sciences, Nuclear physics, Cross section (physics), 0103 physical sciences, Neutron, Nuclear Experiment, 010306 general physics, Anisotropy

Abstract

Fission fragment angular distributions can provide an important constraint on fission theory, improving predictive fission codes, and are a prerequisite for a precise ratio cross section measurement. Available anisotropy data is sparse, especially at neutron energies above 5 MeV. For the first time, a three-dimensional tracking detector is employed to study fragment emission angles and provide a direct measurement of angular anisotropy. The Neutron Induced Fission Fragment Tracking Experiment (NIFFTE) collaboration has deployed the fission time projection chamber (fissionTPC) to measure nuclear data with unprecedented precision. The fission fragment anisotropy of $^{235}$U has been measured over a wide range of incident neutron energies from 180 keV to 200 MeV; a careful study of the systematic uncertainties complement the data.

Published

2019

5. Erratum: Informing direct neutron capture on tin isotopes near the N=82 shell closure [Phys. Rev. C 99 , 041302(R) (2019)]

Author

J. M. Allmond, K.L. Jones, Luke Titus, D. W. Bardayan, Dan Shapira, William A. Peters, Jolie Cizewski, Kyle Schmitt, Milan Matos, C. D. Nesaraja, R. L. Kozub, Patrick O'Malley, Brett Manning, Kelly Chipps, M. E. Howard, J. F. Liang, Andrew Ratkiewicz, S. D. Pain, S. T. Pittman, Filomena Nunes, Goran Arbanas, Sunghoon Ahn, K. Y. Chae, and Michael S. Smith

Subjects

Nuclear physics, Physics, Neutron capture, Isotopes of tin, Closure (topology), Shell (structure)

Published

2019

6. Constraining spectroscopic factors near the r -process path using combined measurements: Kr86 (d, p)87Kr

Author

J. A. Cizewski, Kelly Chipps, S. Burcher, Sunghoon Ahn, Filomena Nunes, Paul Thompson, C. Thornsberry, Thomas Baumann, Brett Manning, G. Cerizza, S. J. Williams, S. J. Lonsdale, S. Ota, D. W. Bardayan, Fernando Montes, Patrick O'Malley, Andrew Ratkiewicz, R. L. Kozub, D. Bazin, S. D. Pain, T.R. Baugher, K.L. Jones, J. Pereira, and David Walter

Subjects

Physics, Path (graph theory), r-process, Computational physics

Published

2019

7. Fission fragment yields and total kinetic energy release in neutron-induced fission of235,238U,and239Pu

Author

Kyle Schmitt, Fredrik Tovesson, Brett Manning, Shea Mosby, V. Geppert-Kleinrath, D.A. Mayorov, and D. L. Duke

Subjects

Nuclear fission product, Time projection chamber, Materials science, 010308 nuclear & particles physics, Fission, Physics::Instrumentation and Detectors, Physics, QC1-999, Nuclear Theory, Kinetic energy, 01 natural sciences, Nuclear physics, Nuclear fission, Scientific method, Ionization, 0103 physical sciences, Neutron, 010306 general physics, Nuclear Experiment

Abstract

Different aspects of the nuclear fission process have been studied at Los Alamos Neutron Science Center (LANSCE) using various instruments and experimental techniques. Properties of the fragments emitted in fission have been investigated using Frisch-grid ionization chambers, a Time Projection Chamber (TPC), and the SPIDER instrument which employs the 2v-2E method. These instruments and experimental techniques have been used to determine fission product mass yields, the energy dependent total kinetic energy (TKE) release, and anisotropy in neutron-induced fission of U-235, U-238 and Pu-239.

Published

2018

8. Performance of a MICROMEGAS-based TPC in a high-energy neutron beam

Author

S. Watson, Jonathan B. King, Joshua Gearhart, Uwe Greife, Michael Heffner, Robert Casperson, L. Snyder, Michael P. Mendenhall, D. L. Duke, Walid Younes, L. Yao, D. Cebra, D. Isenhower, R. S. Towell, Joshua A. Magee, C. Hagmann, Fredrik Tovesson, V. Geppert-Kleinrath, Nicholas Walsh, Samuele Sangiorgio, Brett Manning, T. Classen, Walter Loveland, Kyle Schmitt, D. Hensle, B. Seilhan, D. Higgins, Nathaniel Bowden, J. Bundgaard, and Jennifer Lynn Klay

Subjects

Physics, Nuclear and High Energy Physics, Time projection chamber, Physics - Instrumentation and Detectors, 010308 nuclear & particles physics, Physics::Instrumentation and Detectors, FOS: Physical sciences, MicroMegas detector, Instrumentation and Detectors (physics.ins-det), Neutron radiation, 01 natural sciences, Charged particle, Particle detector, Ion, Nuclear physics, Recoil, 0103 physical sciences, Measuring instrument, Nuclear Experiment (nucl-ex), 010306 general physics, Nuclear Experiment, Instrumentation

Abstract

The MICROMEGAS (MICRO-MEsh GAseous Structure) charge amplification structure has found wide use in many detection applications, especially as a gain stage for the charge readout of Time Projection Chambers (TPCs). Here we report on the behavior of a MICROMEGAS TPC when operated in a high-energy (up to 800 MeV ) neutron beam. It is found that neutron-induced reactions can cause discharges in some drift gas mixtures that are stable in the absence of the neutron beam. The discharges result from recoil ions close to the MICROMEGAS that deposit high specific ionization density and have a limited diffusion time. For a binary drift gas, increasing the percentage of the molecular component (quench gas) relative to the noble component and operating at lower pressures generally improves stability.

Published

2017

9. High Precision Neutron-Induced Fission Cross Sections Using a Time Projection Chamber

Author

Brett Manning

Subjects

Physics, Nuclear physics, Time projection chamber, Fission, Nuclear fission, Nuclear engineering, Neutron

Published

2017

10. Neutron-Induced Charged Particle Measurements at LANSCE in the Interest of P-Process Nucleosynthesis

Author

Toshihiko Kawano, Robert C. Haight, Brett Manning, Shea Mosby, and Hye Young Lee

Subjects

Nuclear physics, Physics, Particle physics, Nucleosynthesis, Neutron, p-process, Charged particle

Published

2017

11. 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

12. Total kinetic energy release inPu239(n,f)post-neutron emission from 0.5 to 50 MeV incident neutron energy

Author

Fredrik Tovesson, D. Shields, K. Meierbachtol, R. Meharchand, D. L. Duke, V. Geppert-Kleinrath, Brett Manning, and Shea Mosby

Subjects

Physics, 010308 nuclear & particles physics, Fission, Neutron emission, Astrophysics::High Energy Astrophysical Phenomena, Nuclear Theory, Center (category theory), Kinetic energy, 01 natural sciences, Neutron temperature, Nuclear physics, 0103 physical sciences, Ionization chamber, Neutron, Atomic physics, Nuclear Experiment, 010306 general physics, Energy (signal processing)

Abstract

The average total kinetic energy $(\overline{TKE})$ in $^{239}\mathrm{Pu}(n,f)$ has been measured for incident neutron energies between 0.5 and 50 MeV. The experiment was performed at the Los Alamos Neutron Science Center (LANSCE) using the neutron time-of-flight technique, and the kinetic energy of fission fragments post-neutron emission was measured in a double Frisch-gridded ionization chamber. This represents the first experimental study of the energy dependence of $\overline{TKE}$ in $^{239}\mathrm{Pu}$ above neutron energies of 6 MeV.

Published

2016

13. Using a Time Projection Chamber to Measure High Precision Neutron-Induced Fission Cross Sections

Author

Brett Manning

Subjects

Nuclear physics, Physics, Cross section (physics), Time projection chamber, Fission, Measure (physics), Neutron, Beam (structure), Particle identification

Abstract

2014 LANSCE run cycle data will provide a preliminary 239Pu(n,f) cross section and will quantify uncertainties: PID and Target/beam non-uniformities. Continued running during the 2015 LANSCE run cycle: Thin targets to see both fission fragments and 239Pu(n,f) cross section and fully quantified uncertainties

Published

2015

14. Measuring Cross-Section and Estimating Uncertainties with the fissionTPC

Author

S. Sangiorgio, B. Seilhan, Nathaniel Bowden, and Brett Manning

Subjects

Cross section (physics), Geodesy, Geology

Published

2015

15. 2π1νstates populated inTe135fromBe9-induced reactions with aSn132beam

Author

C. R. Bingham, J. C. Batchelder, J. M. Allmond, R. L. Varner, A. Ayres, Michael Scott Smith, N. J. Stone, A. Bey, Carl J Gross, P. E. Mueller, B. A. Brown, Brett Manning, K. L. Jones, Dan Shapira, D. W. Stracener, M. E. Howard, W. A. Peters, J. R. Beene, Andrew Stuchbery, Elizabeth Padilla-Rodal, J. F. Liang, Andrew Ratkiewicz, Steven D. Pain, Kyle Schmitt, Caroline D Nesaraja, Chang-Hong Yu, D. C. Radford, and A. Galindo-Uribarri

Subjects

Physics, Nuclear and High Energy Physics, SHELL model, Atomic physics, Born approximation, Nucleon, Multiplet, Energy (signal processing), Beam (structure), Spin-½

Abstract

$\ensuremath{\gamma}$-ray transitions in ${}^{134}\text{Te}$, ${}^{135}\text{Te}$, and ${}^{136}\text{Te}$ were measured from ${}^{9}\text{Be}$-induced reactions with a radioactive ${}^{132}\text{Sn}$ beam at a sub-Coulomb barrier energy of 3 MeV per nucleon using particle-$\ensuremath{\gamma}$ coincidence spectroscopy. The transitions were selected by gating on alpha-like particles in a CsI detector following a combination of $({}^{9}\text{Be},\ensuremath{\alpha}1n)$, $({}^{9}\text{Be},\ensuremath{\alpha}2n)$, and $({}^{9}\text{Be},\ensuremath{\alpha}3n)$ incomplete fusion-evaporation reactions. Distorted-wave Born approximation calculations suggest little to no contribution from the $({}^{9}\text{Be},{}^{7}\text{He})$, $({}^{9}\text{Be},{}^{6}\text{He})$, and $({}^{9}\text{Be},{}^{5}\text{He})$ direct reactions.$\ensuremath{\gamma}$-ray transitions from previously known ${2}^{+}\ensuremath{\bigotimes}\ensuremath{\nu}\phantom{\rule{0.16em}{0ex}}2{f}_{7/2}$ and ${4}^{+}\ensuremath{\bigotimes}\ensuremath{\nu}\phantom{\rule{0.16em}{0ex}}2{f}_{7/2}$ multiplet members in ${}^{135}\text{Te}$ are observed. A new $\ensuremath{\gamma}$ ray is observed, assigned to the third-excited state in ${}^{135}\text{Te}$, and new ${2}^{+}\ensuremath{\bigotimes}\ensuremath{\nu}\phantom{\rule{0.16em}{0ex}}2{f}_{7/2}$ multiplet members are suggested. In addition, spin assignments are made by using recent one-neutron transfer data. The updated experimental data for ${}^{135}\text{Te}$ are compared to shell-model calculations for a relatively complete set of states up to the yrast ${15/2}^{\ensuremath{-}},{4}^{+}\ensuremath{\bigotimes}\ensuremath{\nu}\phantom{\rule{0.16em}{0ex}}2{f}_{7/2}$ multiplet member at 1505 keV.

Published

2014

16. GAMMASPHERE AND ORRUBA: DUAL DETECTORS FOR EXPERIMENTAL STRUCTURE STUDIES

Author

William A. Peters, Shaofei Zhu, Brett Manning, D. W. Bardayan, R. L. Kozub, C. J. Lister, D. Seweryniak, M. P. Carpenter, J. A. Cizewski, Kelly Chipps, J. C. Blackmon, Milan Matos, C. Shand, S. Hardy, M. E. Howard, Andrew Ratkiewicz, K.L. Jones, and S. D. Pain

Subjects

Nuclear physics, Physics, Detector, Gammasphere, DUAL (cognitive architecture)

Published

2013

17. BETA-DELAYED NEUTRON SPECTROSCOPY FOR r-PROCESS NUCLEOSYNTHESIS

Author

M. Matos, M. E. Howard, P. Copp, S. Padgett, Stan Paulauskas, Andrew Ratkiewicz, M. Al-Shudifat, A. J. Mendez, J. C. Blackmon, K. T. Schmitt, Carl J Gross, L. Cartegni, David Walter, William A. Peters, K. Miernik, C. Rasco, I. Spassova, A. Fijałkowska, S. H. Liu, Brett Manning, C. Jost, Jolie Cizewski, D. W. Stracener, F. Raiola, N. T. Brewer, R. Grzywacz, S. V. Ilyushkin, David Miller, M. Madurga, P. D. O'Malley, K. P. Rykaczewski, E.F. Zganjar, J. C. Batchelder, M. Wolińska-Cichocka, E. H. Wang, F. Sarazin, D. W. Bardayan, and Catalin Matei

Subjects

Physics, Nuclear physics, Big Bang nucleosynthesis, Nucleosynthesis, r-process, Spectroscopy, Beta (finance), Delayed neutron

Published

2013

18. PROBING SINGLE-NEUTRON LEVELS IN 127,129Sn VIA TRANSFER REACTIONS

Author

J. R. Beene, A. Galindo-Uribarri, Kelly Chipps, J. M. Allmond, K.L. Jones, D. C. Radford, William A. Peters, C. D. Nesaraja, S. T. Pittman, Brett Manning, S. D. Pain, M. E. Howard, D. W. Bardayan, Andrew Ratkiewicz, Patrick O'Malley, J. A. Cizewski, Milan Matos, Kyle Schmitt, Elizabeth Padilla-Rodal, K. Y. Chae, Dan Shapira, S. Ahn, J. F. Liang, R. L. Kozub, and Michael S. Smith

Subjects

Radioactive ion beams, Materials science, SHELL model, Neutron, Atomic physics

Published

2013

19. GYROMAGNETIC RATIOS IN NEUTRON-RICH NUCLEI BY THE RECOIL IN VACUUM TECHNIQUE

Author

Paul Hausladen, C. Baktash, A. Galindo-Uribarri, C.-H. Yu, Brett Manning, J. R. Beene, N. J. Stone, J. F. Liang, Karin Lagergren, Elizabeth Padilla-Rodal, M. Danchev, G. J. Kumbartzki, N. Benczer-Koller, Andrew Stuchbery, M. E. Howard, C. R. Bingham, J. C. Batchelder, Y. Larochelle, J. M. Allmond, R. L. Varner, S. D. Pain, and D. C. Radford

Subjects

Nuclear physics, Physics, Recoil, Magnetic moment, Neutron, Coulomb excitation, Atomic physics

Published

2013

20. TRANSFER REACTION EXPERIMENTS WITH FISSION FRAGMENTS

Author

J. M. Allmond, K.L. Jones, J. A. Cizewski, A. Galindo-Uribarri, D. C. Radford, A. Bey, S. D. Pain, R. L. Kozub, J. R. Beene, Brett Manning, and D. W. Bardayan

Subjects

Physics, Inverse kinematics, Fission, Astrophysics::High Energy Astrophysical Phenomena, Transfer (computing), Gamma ray, Silicon detector, Atomic physics, Nuclear Experiment, Measure (mathematics), Charged particle, Coincidence

Abstract

Two generalized transfer reaction techniques have been used to exploit these beams in regions of the nuclear chart around N = 50 and N = 82. The first employs large silicon detector arrays to measure protons emitted from the (d,p) reaction in inverse kinematics [2 6]. The second uses HYBALL to detect the charged particles emitted from ( 9 Be, 8 Be), and ( 13 C, 12 C) reactions with gamma rays measured in coincidence in CLARION [6 7].

Published

2013

21. Neutron transfer reactions with tin beams and r-process nucleosynthesis

Author

K. Y. Chae, Filomena Nunes, R. L. Kozub, K. L. Jones, Brett Manning, S. Ahn, R. Kapler, Caroline D Nesaraja, M. Matos, S. T. Pittman, Robert Hatarik, Dan Shapira, J. C. Blackmon, K. T. Schmitt, D. W. Bardayan, Kelly Chipps, J. A. Cizewski, W. A. Peters, S. Hardy, M. E. Howard, Patrick O'Malley, Steven D. Pain, J. F. Liang, Brian Moazen, Andrew Ratkiewicz, Michael Scott Smith, and Goran Arbanas

Subjects

Nuclear physics, Physics, chemistry, Nucleosynthesis, chemistry.chemical_element, r-process, Neutron, Tin

Published

2013

22. Studies of fission fragment properties at the Los Alamos Neutron Science Center (LANSCE)

Author

V. Geppert-Kleinrath, Brett Manning, D.A. Mayorov, D. L. Duke, and Fredrik Tovesson

Subjects

Physics, Time projection chamber, Spectrometer, 010308 nuclear & particles physics, Fission, QC1-999, Nuclear Theory, Nuclear data, Kinetic energy, 01 natural sciences, Particle detector, Nuclear physics, 0103 physical sciences, Neutron, Nuclear Experiment, 010306 general physics, Nucleon

Abstract

Nuclear data related to the fission process are needed for a wide variety of research areas, including fundamental science, nuclear energy and non-proliferation. While some of the relevant data have been measured to the required accuracies there are still many aspects of fission that need further investigation. One such aspect is how Total Kinetic Energy (TKE), fragment yields, angular distributions and other fission observables depend on excitation energy of the fissioning system. Another question is the correlation between mass, charge and energy of fission fragments. At the Los Alamos Neutron Science Center (LANSCE) we are studying neutron-induced fission at incident energies from thermal up to hundreds of MeV using the Lujan Center and Weapons Neutron Research (WNR) facilities. Advanced instruments such as SPIDER (time-of-flight and kinetic energy spectrometer), the NIFFTE Time Projection Chamber (TPC), and Frisch grid Ionization Chambers (FGIC) are used to investigate the properties of fission fragments, and some important results for the major actinides have been obtained.

Published

2017

23. Coupling Gammasphere and ORRUBA

Author

R. L. Kozub, Kelly Chipps, C. J. Lister, William A. Peters, S. D. Pain, J. C. Blackmon, Brett Manning, C. Shand, J. A. Cizewski, D. W. Bardayan, Andrew Ratkiewicz, Milan Matos, K.L. Jones, D. Seweryniak, and S. Hardy

Subjects

Coupling, Radioactive ion beams, Physics, Physics::Instrumentation and Detectors, Astrophysics::High Energy Astrophysical Phenomena, Detector, Gamma ray, Particle identification, Particle detector, Nuclear physics, Coincident, Gammasphere, Atomic physics, Nuclear Experiment

Abstract

The coincident detection of particles and gamma rays allows the study of the structure of exotic nuclei via inverse kinematics reactions using radioactive ion beams and thick targets. We report on the status of the project to couple the highresolution charged-particle detector ORRUBA to Gammasphere, a high-efficiency, high-resolution gamma ray detector.

Published

2013

24. Development of the superorruba detector array and the measurement of single particle states in [sup 81]Ge

Author

L. G. Sobotka, Aderemi S. Adekola, S. T. Pittman, K. Y. Chae, S. Ahn, Michael Scott Smith, B. C. Rasco, D. W. Bardayan, J. C. Blackmon, R. L. Kozub, William A. Peters, J. M. Elson, I. Spassova, Patrick O'Malley, Brett Manning, J. A. Cizewski, M. E. Howard, Kelly Chipps, Milan Matos, C. D. Nesaraja, S. Hardy, K.L. Jones, and S. D. Pain

Subjects

Physics, Silicon, Inverse kinematics, Resolution (electron density), Detector, Solid angle, Nuclear shell model, chemistry.chemical_element, Computational physics, Nuclear physics, chemistry, Nucleosynthesis, Neutron, Nuclear Experiment

Abstract

The study of nuclei far from stability elucidates the evolution of nuclear shell structure, and also affects estimates of heavy element nucleosynthesis in supernova explosions. Measurement of transfer reactions in inverse kinematics with radioactive ion beams is a powerful technique for these types of studies. Rare isotope beams often have relatively low intensities, and this places difficult requirements on the detection systems for reaction products. The detectors must provide large solid angle coverage in the laboratory along with good position and energy resolution. The Super ORRUBA detector array has been developed for such measurements and is comprised of 18 double-sided, nonresistive silicon strip detectors. This configuration features low thresholds and improved resolution over detectors employing charge division. As a first implementation of this system, the 80Ge(d,p)81Ge neutron transfer reaction in inverse kinematics was measured at HRIBF at ORNL, to determine the properties of levels in 81Ge.

Published

2013

25. Single-neutron levels near the N=82 shell closure

Author

J. F. Liang, J. M. Allmond, Dan Shapira, K.L. Jones, R. L. Kozub, J. R. Beene, Milan Matos, Patrick O'Malley, M. E. Howard, S. Ahn, Elizabeth Padilla-Rodal, Michael S. Smith, Kyle Schmitt, Andrew Ratkiewicz, D. C. Radford, William A. Peters, Brett Manning, S. T. Pittman, S. D. Pain, J. A. Cizewski, C. D. Nesaraja, D. W. Bardayan, K. Y. Chae, A. Galindo-Uribarri, and Kelly Chipps

Subjects

Nuclear physics, Angular momentum, Ion beam, Chemistry, Isotopes of tin, Nuclear structure, Shell (structure), Nuclear shell model, Physics::Accelerator Physics, r-process, Neutron, Atomic physics, Nuclear Experiment

Abstract

The (d, p) reaction was measured with the radioactive ion beams of 126Sn and 128Sn in inverse kinematics at the Holifield Radioactive Ion Beam Facility at Oak Ridge National Laboratory, utilizing the Super ORRUBA silicon detector array. Angular distributions of reaction protons were measured for several states in 127Sn and 129Sn to determine angular momentum transfers and deduce spectroscopic factors. Such information is critical for calculating direct (n,γ) cross sections for the r-process as well as for constraining shell model parameters in the A≈130 region. Combined with previous experiments on 130Sn and 132Sn, these results will provide a complete set of (d, p) reaction data on even tin isotopes between stable 124Sn and doubly-magic 132Sn.

Published

2013

26. HRIBF studies of r-process nuclei and first results with the new SuperORRUBA detector

Author

Kelly Chipps, M. E. Howard, K.L. Jones, Andrew Ratkiewicz, S. D. Pain, Brett Manning, D. W. Bardayan, S. Hardy, Kyle Schmitt, S. T. Pittman, Michael S. Smith, S. Ahn, J. A. Cizewski, William A. Peters, Milan Matos, I. Spassova, C. D. Nesaraja, Patrick O'Malley, J. C. Blackmon, S. Strauss, R. L. Kozub, and K. Y. Chae

Subjects

Physics, Nuclear physics, Ion beam, Fission, Nuclear Theory, Detector, Physics::Accelerator Physics, r-process, Atomic physics, Nuclear Experiment, Beam (structure)

Abstract

The astrophysical rapid neutron-capture process (r-process) is believed to have produced approximately half of the nuclear species more massive than Fe. Unfortunately, almost nothing is known about the structure of the majority of the extremely neutron-rich nuclei involved in the reaction flow. At exotic beam facilities such as the Holifield Radioactive Ion Beam Facility (HRIBF), measurements with accelerated beams of fission fragments have provided some of the first spectroscopic information on many r-process nuclei. The new SuperORRUBA (Oak Ridge Rutgers University Barrel Array) detector has been constructed at the HRIBF to study such nuclei, and first results are presented.

Published

2013