48 results on '"Hans P. Mumm"'
Search Results
2. Limits on Sub-GeV Dark Matter from the PROSPECT Reactor Antineutrino Experiment
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J. Koblanski, J. L. Palomino, Chao Zhang, M. P. Mendenhall, Minfang Yeh, A. J. Conant, A. B. Hansell, C. E. Gilbert, Christopher V. Cappiello, B. T. Foust, J. Wilhelmi, J. LaRosa, A. M. Meyer, R. Neilson, J. K. Gaison, J. Maricic, R. Milincic, G. Deichert, T. J. Langford, D. Venegas-Vargas, Jim Napolitano, C. D. Bryan, Xin Lu, P. E. Mueller, R. L. Varner, Nathaniel Bowden, R. Rosero, X. Zhang, Denis E. Bergeron, D. E. Jaffe, J. A. Nikkel, Xiaolu Ji, Hans P. Mumm, S. Hans, D. C. Jones, A. B. Balantekin, M. A. Tyra, A. Woolverton, O. Kyzylova, S. Nour, Anna Erickson, K. M. Heeger, C. E. Lane, Christopher G. White, T. Classen, C. D. Bass, M. J. Dolinski, P. Weatherly, M. V. Diwan, H. R. Band, A. Galindo-Uribarri, B. R. Littlejohn, P. T. Surukuchi, Dmitry A. Pushin, S. Jayakumar, B. Heffron, Xin Qian, and M. Andriamirado
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Physics ,High energy ,010308 nuclear & particles physics ,Astrophysics::High Energy Astrophysical Phenomena ,Dark matter ,Flux ,FOS: Physical sciences ,Cosmic ray ,Astrophysics ,Astrophysics::Cosmology and Extragalactic Astrophysics ,7. Clean energy ,01 natural sciences ,High Energy Physics - Experiment ,High Energy Physics - Experiment (hep-ex) ,High Energy Physics - Phenomenology ,High Energy Physics - Phenomenology (hep-ph) ,Sidereal time ,0103 physical sciences ,Neutrino ,010306 general physics ,Nuclear Experiment - Abstract
If dark matter has mass lower than around 1 GeV, it will not impart enough energy to cause detectable nuclear recoils in many direct-detection experiments. However, if dark matter is upscattered to high energy by collisions with cosmic rays, it may be detectable in both direct-detection experiments and neutrino experiments. We report the results of a dedicated search for boosted dark matter upscattered by cosmic rays using the PROSPECT reactor antineutrino experiment. We show that such a flux of upscattered dark matter would display characteristic diurnal sidereal modulation, and use this to set new experimental constraints on sub-GeV dark matter exhibiting large interaction cross-sections., 11 pages, 8 figures
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- 2021
3. New high-sensitivity searches for neutrons converting into antineutrons and/or sterile neutrons at the HIBEAM/NNBAR experiment at the European Spallation Source
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J. I. Marquez, E. Golubeva, Zurab Berezhiani, B. Z. Kopeliovich, K. Dunne, M. Lindroos, L. Townsend, Takeyasu M. Ito, Agneta Oskarsson, A. Kozela, David Milstead, Samuel Silverstein, D. D. DiJulio, S. Yiu, A. D. Dolgov, Lawrence Heilbronn, P. Fierlinger, A. Tureanu, Christian Bohm, G. Ichikawa, B. Rybolt, E. B. Klinkby, Igor Tkachev, Arkady Vainshtein, Y. N. Pokotilovski, Archil Kobakhidze, Kevin W. Anderson, R. W. Pattie, Y. J. Jwa, Leah Broussard, R. Biondi, B. Kerbikov, David V. Baxter, J. Cedercäll, David Olle Rickard Silvermyr, A. Holley, A. Addazi, A. P. Serebrov, Hans P. Mumm, S. Girmohanta, V. Santoro, Arthur E. Ruggles, P. Geltenbort, Yuri Kamyshkov, H. M. Shimizu, Geoffrey Greene, N. Rizzi, Joshua Barrow, A. Takibayev, Christopher Crawford, T. Greenshaw, N. Rossi, E. Paryev, Thomas Nilsson, A. A. Nepomuceno, Robert Shrock, L. W. Koerner, R. Woracek, T. Johansson, S. Gardiner, L. Varriano, G. Muhrer, Susan Gardner, A. Kupsc, J. M. Richard, Bernhard Meirose, R. Hall-Wilton, Vladimir Gudkov, T. Morishima, J. Makkinje, E. Rinaldi, J. Herrero-Garcia, Michael R. Fitzsimmons, P. S. B. Dev, Y. T. Lee, Erik B. Iverson, K. S. Babu, Y. Yamagata, C. Redding, H. Perrey, Rabindra N. Mohapatra, Albert Young, V. V. Nesvizhevsky, Masaaki Kitaguchi, S. Penttil, G. Brooijmans, Fabrizio Nesti, J. de Vries, Riccardo Bevilacqua, O. Zimmer, Kalliopi Kanaki, Robert Wagner, K. Ramic, E. Kearns, Z. Zhang, K. Nagamoto, L. Zanini, S. Ansell, P. M. Bentley, T. Kittelmann, A. Fomin, T. M. Miller, U. Sarkar, Goran Senjanovic, A. Galindo-Uribarri, W. M. Snow, Pavel Golubev, V. A. Kudryavtsev, M. J. Frost, Z. Kokai, A. Saunders, L. Jönsson, D. Ries, I. Potashnikovav, Institut Laue-Langevin (ILL), ILL, Institut de Physique des 2 Infinis de Lyon (IP2I Lyon), Institut National de Physique Nucléaire et de Physique des Particules du CNRS (IN2P3)-Université Claude Bernard Lyon 1 (UCBL), Université de Lyon-Université de Lyon-Centre National de la Recherche Scientifique (CNRS), and Department of Physics
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baryon number violation ,feebly interacting particles ,European Spallation Source ,baryogenesis ,Physics beyond the Standard Model ,Nuclear Theory ,EXPERIMENTAL LIMIT ,Antineutron ,01 natural sciences ,Subatomär fysik ,ANTIPROTON ANNIHILATION ,n: oscillation ,Subatomic Physics ,[PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex] ,Nuclear Experiment ,sterile ,Physics ,MIRROR MATTER ,new physics ,anti-n ,ddc ,Antimatter ,baryon: asymmetry ,proposed experiment ,DAMA ANNUAL MODULATION ,Nuclear and High Energy Physics ,Particle physics ,Accelerator Physics and Instrumentation ,114 Physical sciences ,Baryon asymmetry ,nuclear physics ,0103 physical sciences ,DARK-MATTER ,mixing ,Neutron ,Sensitivity (control systems) ,[PHYS.PHYS.PHYS-INS-DET]Physics [physics]/Physics [physics]/Instrumentation and Detectors [physics.ins-det] ,TRANSITION OPERATORS ,010306 general physics ,baryon number: violation ,activity report ,010308 nuclear & particles physics ,High Energy Physics::Phenomenology ,Acceleratorfysik och instrumentering ,MAJORANA NEUTRINOS ,sensitivity ,Baryogenesis ,regeneration ,UNIFIED PICTURE ,B-L SYMMETRY ,Baryon number ,BARYON-NUMBER NONCONSERVATION - Abstract
The violation of baryon number, B , is an essential ingredient for the preferential creation of matter over antimatter needed to account for the observed baryon asymmetry in the Universe. However, such a process has yet to be experimentally observed. The HIBEAM/NNBAR program is a proposed two-stage experiment at the European Spallation Source to search for baryon number violation. The program will include high-sensitivity searches for processes that violate baryon number by one or two units: free neutron–antineutron oscillation ( n → n ̄ ) via mixing, neutron–antineutron oscillation via regeneration from a sterile neutron state ( n → [ n ′ , n ̄ ′ ] → n ̄ ), and neutron disappearance (n → n′); the effective Δ B = 0 process of neutron regeneration ( n → [ n ′ , n ̄ ′ ] → n ) is also possible. The program can be used to discover and characterize mixing in the neutron, antineutron and sterile neutron sectors. The experiment addresses topical open questions such as the origins of baryogenesis and the nature of dark matter, and is sensitive to scales of new physics substantially in excess of those available at colliders. A goal of the program is to open a discovery window to neutron conversion probabilities (sensitivities) by up to three orders of magnitude compared with previous searches. The opportunity to make such a leap in sensitivity tests should not be squandered. The experiment pulls together a diverse international team of physicists from the particle (collider and low energy) and nuclear physics communities, while also including specialists in neutronics and magnetics.
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- 2021
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4. Nonfuel antineutrino contributions in the ORNL High Flux Isotope Reactor (HFIR)
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Xiaolu Ji, I. Mitchell, D. Norcini, A. Woolverton, C.E. Gilbert, J. Wilhelmi, Chao Zhang, Aiwu Zhang, S. Nour, M. P. Mendenhall, A. J. Conant, J. L. Palomino-Gallo, Anna Erickson, X. Lu, R. Neilson, E. Romero-Romero, C. E. Lane, Christopher G. White, T. Classen, D. Berish, R. Milincic, D. E. Jaffe, T. J. Langford, R. Rosero, A. B. Hansell, J. A. Nikkel, C. D. Bryan, J. LaRosa, Denis E. Bergeron, B. T. Foust, A. Galindo-Uribarri, B. R. Littlejohn, Jim Napolitano, M. A. Tyra, P. T. Surukuchi, X. Zhang, D. C. Jones, A. B. Balantekin, O. Kyzylova, R. L. Varner, J. K. Gaison, B. Hackett, J. Maricic, Nathaniel Bowden, Hans P. Mumm, K. M. Heeger, Minfang Yeh, J. P. Brodsky, M. V. Diwan, P. E. Mueller, H. R. Band, G. Deichert, Xin Qian, Dmitry A. Pushin, B. Heffron, C. D. Bass, M. J. Dolinski, and S. Hans
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Physics ,Isotope ,010308 nuclear & particles physics ,chemistry.chemical_element ,Uranium ,Oak Ridge National Laboratory ,01 natural sciences ,7. Clean energy ,Nuclear physics ,chemistry ,13. Climate action ,Inverse beta decay ,0103 physical sciences ,Neutron ,Irradiation ,Reactor neutrino ,010306 general physics ,High Flux Isotope Reactor - Abstract
Reactor neutrino experiments have seen major improvements in precision in recent years. With the experimental uncertainties becoming lower than those from theory, carefully considering all sources of ν ¯ e is important when making theoretical predictions. One source of ν ¯ e that is often neglected arises from the irradiation of the nonfuel materials in reactors. The ν ¯ e rates and energies from these sources vary widely based on the reactor type, configuration, and sampling stage during the reactor cycle and have to be carefully considered for each experiment independently. In this article, we present a formalism for selecting the possible ν ¯ e sources arising from the neutron captures on reactor and target materials. We apply this formalism to the High Flux Isotope Reactor (HFIR) at Oak Ridge National Laboratory, the ν ¯ e source for the the Precision Reactor Oscillation and Spectrum Measurement (PROSPECT) experiment. Overall, we observe that the nonfuel ν ¯ e contributions from HFIR to PROSPECT amount to 1% above the inverse beta decay threshold with a maximum contribution of 9% in the 1.8-2.0 MeV range. Nonfuel contributions can be particularly high for research reactors like HFIR because of the choice of structural and reflector material in addition to the intentional irradiation of target material for isotope production. We show that typical commercial pressurized water reactors fueled with low-enriched uranium will have significantly smaller nonfuel ν ¯ e contribution.
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- 2020
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5. X-ray tomography of internal components of the NBS-1 photo-neutron source (Conference Presentation)
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Jacob M. LaManna, Maynard S. Dewey, and Hans P. Mumm
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Physics ,business.industry ,chemistry.chemical_element ,Radioactive waste ,Radiation ,Radium ,Optics ,chemistry ,Primary standard ,Calibration ,Neutron source ,Neutron ,Beryllium ,business - Abstract
The NBS-1 photo-neutron source is the primary standard for neutron calibrations in the United States of America. The source is constructed from 1 g of radium in a RaBr2 salt contained in a Pt-Ir capsule located in the geometric center of a 4 cm beryllium sphere. Since the source was fabricated in 1949, it is desirable to determine the integrity of the capsule and current geometry of the radium salt. Several challenges are presented in inspecting the source such as the high-Z materials used for the capsule which make X-ray tomography challenging with lower keV generators and the radioactive material which creates an intense neutron and gamma radiation fields. The radiation emitted from the source makes it impractical to move the source to a capable imaging facility and makes it difficult to work with as it is not possible to handle directly. To overcome these issues and allow for a feasibility study, a dummy source has been constructed using PbBr2 powder. This talk will provide background on the dummy source and the results of the feasibility study to determine if it possible to relocate a current X-ray system to the neutron calibration facility to inspect the NBS-1 source.
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- 2019
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6. Measurement of the Antineutrino Spectrum from U235 Fission at HFIR with PROSPECT
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D. Davee, G. Deichert, D. Norcini, Michael Febbraro, R. L. Varner, J. M. Minock, M. V. Diwan, Chao Zhang, M. P. Mendenhall, A. B. Hansell, X. Zhang, B. Viren, J. T. Matta, Hans P. Mumm, H. R. Band, B. T. Foust, A. Galindo-Uribarri, Anna Erickson, B. R. Littlejohn, J. Nikkel, J. Wilhelmi, Y-R Yen, D. C. Jones, J. Insler, J. J. Cherwinka, A. B. Balantekin, S. Nour, K. Gilje, T. Wise, C. E. Gilbert, P. T. Surukuchi, S. Hans, D. Berish, O. Kyzylova, K. M. Heeger, D. E. Jaffe, C. D. Bryan, M. J. Dolinski, E. Romero-Romero, Aiwu Zhang, A. J. Conant, R. Neilson, J. LaRosa, P. E. Mueller, M. A. Tyra, Richard Rosero, Jim Napolitano, Denis E. Bergeron, D. J. Dean, Dmitry A. Pushin, Minfang Yeh, C.D. Bass, R. D. McKeown, B. T. Hackett, Xin Lu, Andrew A. Cox, Xiaolu Ji, J. K. Gaison, J. P. Brodsky, Xin Qian, T. Classen, Dusan Sarenac, A. B. Telles, D. A. Martinez Caicedo, C. E. Lane, T. J. Langford, Christopher G. White, J. Ashenfelter, and Nathaniel Bowden
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Semileptonic decay ,Physics ,Fission ,General Physics and Astronomy ,chemistry.chemical_element ,Inverse ,Uranium ,Enriched uranium ,01 natural sciences ,7. Clean energy ,Nuclear physics ,chemistry ,0103 physical sciences ,010306 general physics ,Neutrino oscillation ,Energy (signal processing) ,High Flux Isotope Reactor - Abstract
This Letter reports the first measurement of the ^{235}U ν[over ¯]_{e} energy spectrum by PROSPECT, the Precision Reactor Oscillation and Spectrum experiment, operating 7.9 m from the 85 MW_{th} highly enriched uranium (HEU) High Flux Isotope Reactor. With a surface-based, segmented detector, PROSPECT has observed 31678±304(stat) ν[over ¯]_{e}-induced inverse beta decays, the largest sample from HEU fission to date, 99% of which are attributed to ^{235}U. Despite broad agreement, comparison of the Huber ^{235}U model to the measured spectrum produces a χ^{2}/ndf=51.4/31, driven primarily by deviations in two localized energy regions. The measured ^{235}U spectrum shape is consistent with a deviation relative to prediction equal in size to that observed at low-enriched uranium power reactors in the ν[over ¯]_{e} energy region of 5-7 MeV.
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- 2019
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7. The Radioactive Source Calibration System of the PROSPECT Reactor Antineutrino Detector
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R. Rosero, Denis E. Bergeron, T. J. Langford, R. L. Varner, R. D. McKeown, Chao Zhang, M. P. Mendenhall, J. Ashenfelter, M. V. Diwan, Xin Qian, Nathaniel Bowden, X. Lu, Aiwu Zhang, J. Wilhelmi, D. A. Martinez Caicedo, D. Norcini, J. T. Matta, A. B. Telles, Y-R Yen, G. Deichert, C. D. Bass, M. J. Dolinski, Hans P. Mumm, Jim Napolitano, C.E. Gilbert, J. P. Brodsky, D. C. Jones, J. Insler, A. B. Balantekin, O. Kyzylova, J. J. Cherwinka, R. Neilson, A. B. Hansell, K. M. Heeger, P. E. Mueller, B. Hackett, H. R. Band, B. T. Foust, S. Hans, C. E. Lane, X. Zhang, Dmitry A. Pushin, A. Galindo-Uribarri, B. R. Littlejohn, E. Romero-Romero, J. LaRosa, D. E. Jaffe, Minfang Yeh, S. Nour, P. T. Surukuchi, J. A. Nikkel, Anna Erickson, T. Wise, D. Berish, Christopher G. White, T. Classen, Dusan Sarenac, M. A. Tyra, Michael Febbraro, B. Viren, C. D. Bryan, A. J. Conant, J. K. Gaison, and D. J. Dean
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Physics ,Nuclear and High Energy Physics ,Photomultiplier ,Physics - Instrumentation and Detectors ,010308 nuclear & particles physics ,Physics::Instrumentation and Detectors ,Radioactive source ,Nuclear engineering ,Detector ,FOS: Physical sciences ,Instrumentation and Detectors (physics.ins-det) ,Nuclear reactor ,Oak Ridge National Laboratory ,7. Clean energy ,01 natural sciences ,law.invention ,Physics::Geophysics ,law ,Inverse beta decay ,0103 physical sciences ,High Energy Physics::Experiment ,Neutrino ,010306 general physics ,Instrumentation ,High Flux Isotope Reactor - Abstract
The Precision Reactor Oscillation and Spectrum (PROSPECT) Experiment is a reactor neutrino experiment designed to search for sterile neutrinos with a mass on the order of 1 eV/c$^2$ and to measure the spectrum of electron antineutrinos from a highly-enriched $^{235}$U nuclear reactor. The PROSPECT detector consists of an 11 by 14 array of optical segments in $^{6}$Li-loaded liquid scintillator at the High Flux Isotope Reactor in Oak Ridge National Laboratory. Antineutrino events are identified via inverse beta decay and read out by photomultiplier tubes located at the ends of each segment. The detector response is characterized using a radioactive source calibration system. This paper describes the design, operation, and performance of the PROSPECT source calibration system.
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- 2019
8. Experimental Upper Bound and Theoretical Expectations for Parity-Violating Neutron Spin Rotation in 4He
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M. Sarsour, Jeffrey S. Nico, S. B. Walbridge, E. I. Sharapov, Hans P. Mumm, T. D. Bass, D. M. Markoff, J. C. Horton, H. E. Swanson, A. M. Micherdzinska, C.R. Huffer, D. Luo, C.D. Bass, Bret E. Crawford, J. M. Dawkins, V. Zhumabekova, K. Gan, W. M. Snow, and Blayne Heckel
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Quantum chromodynamics ,Physics ,Particle physics ,010308 nuclear & particles physics ,Nuclear Theory ,FOS: Physical sciences ,Parity (physics) ,Weak interaction ,01 natural sciences ,Upper and lower bounds ,Article ,Amplitude ,0103 physical sciences ,Neutron ,High Energy Physics::Experiment ,Analysis tools ,Nuclear Experiment (nucl-ex) ,010306 general physics ,Nucleon ,Nuclear Experiment - Abstract
Neutron spin rotation is expected from quark-quark weak interactions in the Standard Model, which induce weak interactions among nucleons that violate parity. We present the results from an experiment searching for the effect of parity violation via the spin rotation of polarized neutrons in a liquid $^{4}$He medium. The value for the neutron spin rotation angle per unit length in $^{4}$He, $d\phi/dz =(+2.1 \pm 8.3 (stat.) \pm 2.9 (sys.))\times10^{-7}$ rad/m, is consistent with zero. The result agrees with the best current theoretical estimates of the size of nucleon-nucleon weak amplitudes from other experiments and with the expectations from recent theoretical approaches to weak nucleon-nucleon interactions. In this paper we review the theoretical status of parity violation in the $\vec{n}+^{4}$He system and discuss details of the data analysis leading to the quoted result. Analysis tools are presented that quantify systematic uncertainties in this measurement and that are expected to be essential for future measurements., Comment: 15 pages, 7 figures
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- 2019
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9. Precision neutron flux measurement using the Alpha-Gamma device
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Geoffrey Greene, Hans P. Mumm, Nadia Fomin, W. M. Snow, Evan R. Adamek, Jeffrey S. Nico, Shannon Fogwell Hoogerheide, David M. Gilliam, and Maynard S. Dewey
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Physics ,010308 nuclear & particles physics ,Astrophysics::High Energy Astrophysical Phenomena ,QC1-999 ,chemistry.chemical_element ,Germanium ,Neutron radiation ,01 natural sciences ,Nuclear physics ,Cross section (physics) ,Neutron capture ,chemistry ,Neutron flux ,0103 physical sciences ,NIST ,Neutron ,010306 general physics ,Boron ,Nuclear Experiment - Abstract
The Alpha-Gamma device at the National Institute of Standards and Technology (NIST) utilizes neutron capture on a totally absorbing 10B deposit to measure the absolute neutron flux of a monochromatic cold neutron beam. Gammas produced by the boron capture are counted using high purity germanium detectors, which are calibrated using a well-measured 239Pu alpha source and the alpha-to-gamma ratio from neutron capture on a thin 10B target. This device has been successfully operated and used to calibrate the neutron flux monitor for the BL2 neutron lifetime experiment at NIST. It is also being used for a measurement of the 6Li(n,t)4He cross section. We shall present its principle of operation along with the current and planned projects involving the Alpha-Gamma device, including the recalibration of the U.S. national neutron standard NBS-1 and (n,f) cross section measurements of 235U.
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- 2019
10. Survival analysis approach to account for non-exponential decay rate effects in lifetime experiments
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A. Yue, P. R. Huffman, D.E. Marley, Maynard S. Dewey, K.W. Schelhammer, Alan K. Thompson, Kevin J. Coakley, Hans P. Mumm, Michael G. Huber, C.R. Huffer, and C. O׳Shaughnessy
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Systematic error ,Physics ,Nuclear and High Energy Physics ,Competing risks ,01 natural sciences ,Exponential function ,010104 statistics & probability ,Survival probability ,Magnetic trap ,0103 physical sciences ,Neutron ,Statistical physics ,0101 mathematics ,Exponential decay ,010306 general physics ,Instrumentation ,Survival analysis - Abstract
In experiments that measure the lifetime of trapped particles, in addition to loss mechanisms with exponential survival probability functions, particles can be lost by mechanisms with non-exponential survival probability functions. Failure to account for such loss mechanisms produces systematic measurement error and associated systematic uncertainties in these measurements. In this work, we develop a general competing risks survival analysis method to account for the joint effect of loss mechanisms with either exponential or non-exponential survival probability functions, and a method to quantify the size of systematic effects and associated uncertainties for lifetime estimates. As a case study, we apply our survival analysis formalism and method to the Ultra Cold Neutron lifetime experiment at NIST. In this experiment, neutrons can escape a magnetic trap before they decay due to a wall loss mechanism with an associated non-exponential survival probability function.
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- 2016
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11. Neutron-antineutron oscillations: Theoretical status and experimental prospects
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Yuri Kamyshkov, Ayman I. Hawari, Amit Roy, Lawrence W. Townsend, T. Gabriel, Chris Quigg, Robert W. Pattie, Hans P. Mumm, A. Serebrov, P. L. McGaughey, L. Okun, Masaaki Kitaguchi, G. Brooijmans, Lawrence Heilbronn, S. Striganov, B. Z. Kopeliovich, R. Van Kooten, Zurab Berezhiani, Mingshui Chen, Franz X. Gallmeier, K. S. Ganezer, Calvin A. Johnson, Luis A. Castellanos, M. Bergevin, N.V. Mokhov, Ramanath Cowsik, B. Hartfiel, Saptaparna Bhattacharya, E. B. Dees, Arkady Vainshtein, Rabindra N. Mohapatra, Albert Young, Avraham Gal, R. Tschirhart, Michael Mocko, Utpal Sarkar, M. Frost, Geoffrey Greene, V. B. Kopeliovich, Alexander Saunders, E. J. Ramberg, Zhehui Wang, G. Muhrer, S. K. L. Sjue, Arthur E. Ruggles, Prasanta Kumar Das, D. G. Phillips, A. Ray, A. K. Sikdar, K. S. Babu, H. M. Shimizu, V. A. Kuzmin, William Snow, J. A. Crabtree, B. Kerbikov, E. Golubeva, A. D. Dolgov, Chen-Yu Liu, David V. Baxter, C. E. Coppola, Robert Shrock, Phillip D. Ferguson, and Sw. Banerjee
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Cold neutron source ,Quasi-free condition ,Physics - Instrumentation and Detectors ,Nuclear Theory ,Proton decay ,media_common.quotation_subject ,General Physics and Astronomy ,FOS: Physical sciences ,Physics and Astronomy(all) ,Antineutron ,01 natural sciences ,High Energy Physics - Experiment ,Nuclear physics ,Nuclear Theory (nucl-th) ,High Energy Physics - Experiment (hep-ex) ,Baryon asymmetry ,High Energy Physics - Phenomenology (hep-ph) ,0103 physical sciences ,Baryon number violation ,Spallation ,Neutron ,Nuclear Experiment (nucl-ex) ,Nuclear Experiment ,010306 general physics ,media_common ,Physics ,Annihilation ,010308 nuclear & particles physics ,Instrumentation and Detectors (physics.ins-det) ,Neutron radiation ,Universe ,High Energy Physics - Phenomenology ,Neutrino - Abstract
This paper summarizes the relevant theoretical developments, outlines some ideas to improve experimental searches for free neutron-antineutron oscillations, and suggests avenues for future improvement in the experimental sensitivity., Comment: Submitted to Physics Reports
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- 2016
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12. Optimum lithium loading of a liquid scintillator for neutron and neutrino detection
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S. Nour, M. A. Tyra, Hans P. Mumm, Denis E. Bergeron, T. J. Langford, and J. La Rosa
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Physics ,Nuclear and High Energy Physics ,Scintillation ,Physics::Instrumentation and Detectors ,010308 nuclear & particles physics ,Liquid scintillation counting ,Analytical chemistry ,chemistry.chemical_element ,Scintillator ,01 natural sciences ,030218 nuclear medicine & medical imaging ,03 medical and health sciences ,Neutron capture ,0302 clinical medicine ,Neutrino detector ,chemistry ,0103 physical sciences ,Neutron ,Lithium ,Nuclear Experiment ,Neutral particle ,Instrumentation - Abstract
Neutral particle detection in high-background environments is greatly aided by the ability to easily load 6Li into liquid scintillators. We describe a readily available and inexpensive liquid scintillation cocktail stably loaded with a Li mass fraction up to 1 %. Compositions that give thermodynamically stable microemulsions (reverse-micellar systems) were explored, using a Compton spectrum quenching technique to distinguish these from unstable emulsions. Scintillation light yield and transmittance were characterized. Pulse shape discrimination (PSD) was measured using a 252Cf source, showing that electron-like and proton-like recoil events are well-resolved even for Li loading up to 1 %, providing a means of background suppression in neutron/neutrino detectors. While samples in this work were prepared with nat Li (7.59 % 6Li), the neutron capture peak was clearly visible in the PSD spectrum; this implies that while extremely high capture efficiency could be achieved with 6Li-enriched material, a very inexpensive neutron-sensitive detector can be prepared with nat Li.
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- 2020
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13. Performance of a segmented $^{6}$Li-loaded liquid scintillator detector for the PROSPECT experiment
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Dmitry A. Pushin, M. A. Tyra, C. E. Lane, J. P. Brodsky, R. Rosero, Minfang Yeh, Denis E. Bergeron, T. J. Langford, Chao Zhang, M. P. Mendenhall, R. D. McKeown, A. B. Hansell, H. R. Band, S. Nour, Anna Erickson, J. Ashenfelter, D. Norcini, J. J. Cherwinka, T. Wise, D. Berish, K. Gilje, Hans P. Mumm, J. Wilhelmi, Christopher G. White, T. Classen, P. E. Mueller, M. V. Diwan, B. T. Foust, R. Neilson, D. Davee, Nathaniel Bowden, D. A. Martinez Caicedo, F. Lopez, B. Hackett, K. M. Heeger, Y-R Yen, Ke Han, Jim Napolitano, A. Galindo-Uribarri, B. R. Littlejohn, A. Bykadorova Telles, J. T. Matta, D. C. Jones, J. Insler, A. B. Balantekin, E. Romero-Romero, O. Kyzylova, S. Hans, P. T. Surukuchi, X. Zhang, K. Commeford, G. Deichert, D. E. Jaffe, Aiwu Zhang, J. A. Nikkel, C. D. Bass, M. J. Dolinski, J. M. Wagner, A. J. Conant, J. K. Gaison, B. Heffron, Xin Qian, C. Trinh, J. LaRosa, C. D. Bryan, and J. M. Minock
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Scintillation ,Materials science ,Physics - Instrumentation and Detectors ,010308 nuclear & particles physics ,business.industry ,Physics::Instrumentation and Detectors ,Detector ,Attenuation length ,FOS: Physical sciences ,Instrumentation and Detectors (physics.ins-det) ,Scintillator ,01 natural sciences ,7. Clean energy ,High Energy Physics - Experiment ,Neutron capture ,High Energy Physics - Experiment (hep-ex) ,Optics ,Recoil ,Neutrino detector ,0103 physical sciences ,Neutron detection ,010306 general physics ,business ,Instrumentation ,Mathematical Physics - Abstract
This paper describes the design and performance of a 50 liter, two-segment $^{6}$Li-loaded liquid scintillator detector that was designed and operated as prototype for the PROSPECT (Precision Reactor Oscillation and Spectrum) Experiment. The two-segment detector was constructed according to the design specifications of the experiment. It features low-mass optical separators, an integrated source and optical calibration system, and materials that are compatible with the $^{6}$Li-doped scintillator developed by PROSPECT. We demonstrate a high light collection of 850$\pm$20 PE/MeV, an energy resolution of $\sigma$ = 4.0$\pm$0.2% at 1 MeV, and efficient pulse-shape discrimination of low $dE/dx$ (electronic recoil) and high $dE/dx$ (nuclear recoil) energy depositions. An effective scintillation attenuation length of 85$\pm$3 cm is measured in each segment. The 0.1% by mass concentration of $^{6}$Li in the scintillator results in a measured neutron capture time of $\tau$ = 42.8$\pm$0.2 $\mu s$. The long-term stability of the scintillator is also discussed. The detector response meets the criteria necessary for achieving the PROSPECT physics goals and demonstrates features that may find application in fast neutron detection., Comment: 16 pages, 13 figures; minor edits to design detail and references
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- 2018
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14. First search for short-baseline neutrino oscillations at HFIR with PROSPECT
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R. Neilson, Lindsey J. Bignell, D. E. Jaffe, J. A. Nikkel, J. J. Cherwinka, K. Gilje, C. E. Gilbert, D. Davee, R. L. Varner, A. Galindo-Uribarri, B. R. Littlejohn, Minfang Yeh, D. A. Martinez Caicedo, K. Koehler, C. D. Bryan, D. C. Jones, J. Insler, B. Heffron, H. R. Band, C. D. Bass, M. J. Dolinski, A. B. Hansell, A. B. Balantekin, O. Kyzylova, D. Norcini, A. Bykadorova Telles, R. Sharma, J. LaRosa, J. M. Wagner, C. E. Lane, B. T. Foust, C. Baldenegro, Xin Lu, G. Deichert, P. T. Surukuchi, D. J. Dean, H. Yao, Dusan Sarenac, Michael Febbraro, Ke Han, J. P. Brodsky, R. Rosero, J. Wilhelmi, Andrew A. Cox, M. V. Diwan, Jim Napolitano, Denis E. Bergeron, B. Viren, B. R. White, Aiwu Zhang, Hans P. Mumm, J. Bricco, R. D. McKeown, Chao Zhang, K. Commeford, M. P. Mendenhall, Christopher G. White, Wei Wang, J. T. Matta, T. Classen, F. Lopez, K. M. Heeger, X. Zhang, H. J. Miller, T. J. Langford, J. Ashenfelter, X. Ji, Nathaniel Bowden, S. Hans, B. Seilhan, Dmitry A. Pushin, Xin Qian, S. Nour, Anna Erickson, T. Wise, D. Berish, M. A. Tyra, P. E. Mueller, Y-R Yen, A. Glenn, B. T. Hackett, J. K. Gaison, M. Zhao, E. Romero-Romero, A. J. Conant, J. M. Minock, B. W. Goddard, and C. Trinh
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Physics ,Fission products ,Sterile neutrino ,010308 nuclear & particles physics ,Fission ,Oscillation ,General Physics and Astronomy ,FOS: Physical sciences ,Scintillator ,01 natural sciences ,High Energy Physics - Experiment ,Physics::Geophysics ,Nuclear physics ,High Energy Physics - Experiment (hep-ex) ,Inverse beta decay ,0103 physical sciences ,High Energy Physics::Experiment ,Physics::Chemical Physics ,010306 general physics ,Neutrino oscillation ,High Flux Isotope Reactor - Abstract
This Letter reports the first scientific results from the observation of antineutrinos emitted by fission products of $^{235}$U at the High Flux Isotope Reactor. PROSPECT, the Precision Reactor Oscillation and Spectrum Experiment, consists of a segmented 4 ton $^6$Li-doped liquid scintillator detector covering a baseline range of 7-9 m from the reactor and operating under less than 1 meter water equivalent overburden. Data collected during 33 live-days of reactor operation at a nominal power of 85 MW yields a detection of 25461 $\pm$ 283 (stat.) inverse beta decays. Observation of reactor antineutrinos can be achieved in PROSPECT at 5$\sigma$ statistical significance within two hours of on-surface reactor-on data-taking. A reactor-model independent analysis of the inverse beta decay prompt energy spectrum as a function of baseline constrains significant portions of the previously allowed sterile neutrino oscillation parameter space at 95% confidence level and disfavors the best fit of the Reactor Antineutrino Anomaly at 2.2$\sigma$ confidence level., Comment: 7 pages, 5 figures; v3: Added additional supplemental files
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- 2018
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15. The PROSPECT Reactor Antineutrino Experiment
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J. J. Cherwinka, Aiwu Zhang, K. Gilje, G. Deichert, C. Baldenegro, A. Galindo-Uribarri, B. R. Littlejohn, R. Sharma, P. T. Surukuchi, Wei Wang, E. Romero-Romero, D. Norcini, R. L. Varner, K. Commeford, B. Hackett, C. E. Lane, M. Zhao, Minfang Yeh, H. R. Band, A. B. Hansell, D. A. Martinez Caicedo, A. J. Conant, X. Lu, M. V. Diwan, J. M. Minock, B. T. Foust, J. Boyle, Christopher G. White, S. Nour, T. Classen, Anna Erickson, R. Rosero, B. W. Goddard, J. T. Matta, J. K. Gaison, C.E. Gilbert, H. J. Miller, A. Bykadorova Telles, T. Wise, T. J. Langford, D. Berish, Y-R Yen, Denis E. Bergeron, R. Neilson, D. J. Dean, A. Glenn, Michael Febbraro, J. Ashenfelter, R. D. McKeown, B. Viren, Lindsey J. Bignell, Jim Napolitano, J. Bricco, J. P. Brodsky, P. E. Mueller, D. E. Jaffe, M. A. Tyra, X. Ji, Nathaniel Bowden, X. Zhang, J. A. Nikkel, Ke Han, Chao Zhang, H. Yao, C. Trinh, M. P. Mendenhall, C. D. Bryan, K. Koehler, Hans P. Mumm, F. Lopez, D. C. Jones, J. Insler, K. M. Heeger, A. B. Balantekin, O. Kyzylova, Andrew A. Cox, B. R. White, D. Davee, Dusan Sarenac, J. LaRosa, C. D. Bass, M. J. Dolinski, B. Heffron, J. M. Wagner, Xin Qian, J. Wilhelmi, B. Seilhan, Dmitry A. Pushin, and S. Hans
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Physics ,Nuclear and High Energy Physics ,Sterile neutrino ,Physics - Instrumentation and Detectors ,010308 nuclear & particles physics ,Oscillation ,Physics::Instrumentation and Detectors ,Detector ,High Energy Physics::Phenomenology ,FOS: Physical sciences ,Instrumentation and Detectors (physics.ins-det) ,Parameter space ,Scintillator ,01 natural sciences ,7. Clean energy ,Physics::Geophysics ,Nuclear physics ,Inverse beta decay ,0103 physical sciences ,High Energy Physics::Experiment ,010306 general physics ,Neutrino oscillation ,Instrumentation ,High Flux Isotope Reactor - Abstract
The Precision Reactor Oscillation and Spectrum Experiment, PROSPECT, is designed to make both a precise measurement of the antineutrino spectrum from a highly-enriched uranium reactor and to probe eV-scale sterile neutrinos by searching for neutrino oscillations over meter-long baselines. PROSPECT utilizes a segmented $^6$Li-doped liquid scintillator detector for both efficient detection of reactor antineutrinos through the inverse beta decay reaction and excellent background discrimination. PROSPECT is a movable 4-ton antineutrino detector covering distances of 7m to 13m from the High Flux Isotope Reactor core. It will probe the best-fit point of the $\bar\nu_e$ disappearance experiments at 4$\sigma$ in 1 year and the favored regions of the sterile neutrino parameter space at more than 3$\sigma$ in 3 years. PROSPECT will test the origin of spectral deviations observed in recent $\theta_{13}$ experiments, search for sterile neutrinos, and address the hypothesis of sterile neutrinos as an explanation of the reactor anomaly. This paper describes the design, construction, and commissioning of PROSPECT and reports first data characterizing the performance of the PROSPECT antineutrino detector., Comment: 30 pages, 33 figures; updated with journal revision and reference
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- 2018
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16. Design and performance of a cryogenic apparatus for magnetically trapping ultracold neutrons
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Hans P. Mumm, Kevin J. Coakley, C.M. O'Shaughnessy, K.W. Schelhammer, Liang Yang, John M. Doyle, P. R. Huffman, C.R. Huffer, and P. N. Seo
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Superconductivity ,Physics ,Liquid helium ,General Physics and Astronomy ,chemistry.chemical_element ,Cryocooler ,Neutron radiation ,law.invention ,chemistry ,law ,Magnetic trap ,Ultracold neutrons ,General Materials Science ,Neutron ,Physics::Atomic Physics ,Atomic physics ,Nuclear Experiment ,Helium - Abstract
The cryogenic design and performance of an apparatus used to magnetically confine ultracold neutrons (UCN) is presented. The apparatus is part of an effort to measure the beta-decay lifetime of the free neutron and is comprised of a high-current superconducting magnetic trap that surrounds ∼21 l of isotopically pure 4 He cooled to approximately 250 mK. A 0.89 nm neutron beam can enter the apparatus from one end of the magnetic trap and a light collection system allows visible light generated within the helium by decays to be transported to detectors at room temperature. Two cryocoolers are incorporated to reduce liquid helium consumption.
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- 2014
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17. A low mass optical grid for the PROSPECT reactor antineutrino detector
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M. V. Diwan, J. J. Cherwinka, Hans P. Mumm, K. Gilje, D. Norcini, Michael Febbraro, B. Viren, J. T. Matta, D. E. Jaffe, K. M. Heeger, Y-R Yen, J. A. Nikkel, A. B. Hansell, K. H. Hermanek, X. Lu, T. J. Langford, D. Davee, J. Wilhelmi, D. C. Jones, J. Insler, A.E. Detweiler, J. Ashenfelter, Dmitry A. Pushin, A. J. Conant, A. B. Balantekin, D. A. Martinez Caicedo, O. Kyzylova, H. R. Band, E. Romero-Romero, C. D. Bass, B. T. Foust, M. J. Dolinski, Nathaniel Bowden, C.E. Gilbert, Minfang Yeh, P. E. Mueller, M. A. Tyra, D. J. Dean, C. E. Lane, R. Rosero, J. M. Minock, Xin Qian, Denis E. Bergeron, G. Deichert, R. L. Varner, R. D. McKeown, J. P. Brodsky, Chao Zhang, M. P. Mendenhall, S. Hans, R. Neilson, S. Nour, Anna Erickson, J. LaRosa, T. Wise, D. Berish, Y. Gebre, Jim Napolitano, Aiwu Zhang, A. Galindo-Uribarri, B. R. Littlejohn, P. T. Surukuchi, X. Zhang, B. Hackett, Dusan Sarenac, Ian Gustafson, Christopher G. White, T. Classen, J. K. Gaison, and C. D. Bryan
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Physics ,Physics - Instrumentation and Detectors ,Optics ,business.industry ,Detector ,FOS: Physical sciences ,Instrumentation and Detectors (physics.ins-det) ,business ,Low Mass ,Grid ,Instrumentation ,Mathematical Physics - Abstract
PROSPECT, the Precision Reactor Oscillation and SPECTrum experiment, is a short-baseline reactor antineutrino experiment designed to provide precision measurements of the $^{235}$U product $\overline{\nu}_e$ spectrum of utilizing an optically segmented 4-ton liquid scintillator detector. PROSPECT's segmentation system, the optical grid, plays a central role in reconstructing the position and energy of $\overline{\nu}_e$ interactions in the detector. This paper is the technical reference for this PROSPECT subsystem, describing its design, fabrication, quality assurance, transportation and assembly in detail. In addition, the dimensional, optical and mechanical characterizations of optical grid components and the assembled PROSPECT target are also presented. The technical information and characterizations detailed here will inform geometry-related inputs for PROSPECT physics analysis, and can guide a variety of future particle detection development efforts, such as those using optically reflecting materials or filament-based 3D printing., Comment: 31 pages, 28 figures
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- 2019
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18. Lithium-loaded liquid scintillator production for the PROSPECT experiment
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R. L. Varner, X. Lu, M. V. Diwan, P. E. Mueller, B. Hackett, J. LaRosa, R. Neilson, D. A. Martinez Caicedo, A. J. Conant, A. B. Hansell, D. Davee, Aiwu Zhang, Lindsey J. Bignell, J. T. Matta, X. Zhang, J. J. Cherwinka, B. T. Foust, D. E. Jaffe, A. Galindo-Uribarri, B. R. Littlejohn, P. T. Surukuchi, Y-R Yen, G. Deichert, J. A. Nikkel, Dmitry A. Pushin, J. Wilhelmi, C. Camilo Reyes, T. J. Langford, Christopher G. White, C. D. Bryan, T. Classen, J. Ashenfelter, H. R. Band, Michael Febbraro, S. Campos, B. Hayes, J. K. Gaison, B. Viren, Nathaniel Bowden, M. A. Tyra, Dusan Sarenac, R. Diaz Perez, Xin Qian, C.E. Gilbert, S. Nour, Anna Erickson, T. Wise, D. Berish, C. D. Bass, M. J. Dolinski, S. Hans, J. P. Brodsky, R. Rosero, Denis E. Bergeron, R. D. McKeown, E. Romero-Romero, Minfang Yeh, D. Norcini, Hans P. Mumm, D. J. Dean, K. M. Heeger, Jim Napolitano, D. C. Jones, J. Insler, A. B. Balantekin, O. Kyzylova, C. E. Lane, Chao Zhang, and M. P. Mendenhall
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Optical absorbance ,Physics - Instrumentation and Detectors ,Materials science ,Fabrication ,010308 nuclear & particles physics ,Analytical chemistry ,FOS: Physical sciences ,chemistry.chemical_element ,Instrumentation and Detectors (physics.ins-det) ,Scintillator ,7. Clean energy ,01 natural sciences ,Photon yield ,030218 nuclear medicine & medical imaging ,03 medical and health sciences ,0302 clinical medicine ,chemistry ,Yield (chemistry) ,0103 physical sciences ,Lithium ,Instrumentation ,Mass fraction ,Mathematical Physics - Abstract
This work reports the production and characterization of lithium-loaded liquid scintillator (LiLS) for the Precision Reactor Oscillation and Spectrum Experiment (PROSPECT). Fifty-nine 90 liter batches of LiLS (${}^6{\rm Li}$ mass fraction 0.082%$\pm$0.001%) were produced and samples from all batches were characterized by measuring their optical absorbance relative to air, light yield relative to a pure liquid scintillator reference, and pulse shape discrimination capability. Fifty-seven batches passed the quality assurance criteria and were used for the PROSPECT experiment., 16 pages, 15 figures
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- 2019
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19. Neutron spin rotation measurements
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Shannon Fogwell Hoogerheide, C. Paudel, L. Barrón-Palos, W. M. Snow, J. Fry, K. Korsak, K. Steen, Takuya Okudaira, Christopher Crawford, W. Fox, A. Holly, H. E. Gardiner, Hans P. Mumm, D.A. Mayorov, M. Sarsour, I. Francis, D. Esposito, Aaron Sprow, J. Vanderwerp, Christopher C. Haddock, Bret E. Crawford, Hirohiko M. Shimizu, J. Amadio, Fredrik Tovesson, J. Lieers, P. A. Yergeau, Jeffrey S. Nico, S. Magers, E. Anderson, H. E. Swanson, M. Maldonado-Velázquez, and Swadeshmukul Santra
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Quantum chromodynamics ,Physics ,Nuclear physics ,Coupling constant ,Beamline ,QC1-999 ,Neutron ,Polarimeter ,Weak measurement ,Polarization (waves) ,Nucleon - Abstract
The neutron spin rotation (NSR) collaboration used parity-violating spin rotation of transversely polarized neutrons transmitted through a 0.5 m liquid helium target to constrain weak coupling constants between nucleons. While consistent with theoretical expectation, the upper limit set by this measurement on the rotation angle is limited by statistical uncertainties. The NSR collaboration is preparing a new measurement to improve this statistically-limited result by about an order of magnitude. In addition to using the new high-flux NG-C beam at the NIST Center for Neutron Research, the apparatus was upgraded to take advantage of the larger-area and more divergent NG-C beam. Significant improvements are also being made to the cryogenic design. Details of these improvements and readiness of the upgraded apparatus are presented. We also comment on how recent theoretical work combining effective field theory techniques with the 1/Nc expansion of QCD along with previous NN weak measurements can be used to make a prediction for dϕ/dz in 4He. An experiment using the same apparatus with a room-temperature target was carried out at LANSCE to place limits on parity-conserving rotations from possible fifth-force interactions to complement previous studies. We sought this interaction using a slow neutron polarimeter that passed transversely polarized slow neutrons by unpolarized slabs of material arranged so that this interaction would tilt the plane of polarization and develop a component along the neutron momentum. The results of this measurement and its impact on the neutron-matter coupling gA2 from such an interaction are presented. The NSR collaboration is also preparing a new measurement that uses an upgraded version of the room-temperature target to be run on the NG-C beamline; and it is expected to constrain gA2 by at least two additional orders of magnitude for λc between 1 cm and 1 μm.
- Published
- 2019
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20. Time reversal and the neutron
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Gordon L. Jones, Timothy Chupp, J. F. Wilkerson, Stuart Freedman, Jeffrey S. Nico, Hans P. Mumm, Alejandro Garcia, Robert Cooper, C. Trull, Kevin P. Coulter, Alan K. Thompson, Fred E. Wietfeldt, and B. K. Fujikawa
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Physics ,Semileptonic decay ,Nuclear and High Energy Physics ,Scalar (mathematics) ,Condensed Matter Physics ,Coupling (probability) ,Atomic and Molecular Physics, and Optics ,Nuclear physics ,Amplitude ,Quantum mechanics ,CP violation ,Neutron ,Tensor ,Physical and Theoretical Chemistry ,Pseudovector - Abstract
We have measured the triple correlation $D\langle\vec J_n\rangle/J_n\cdot (\vec\beta_e\times\hat p_\nu)$ with a polarized cold-neutron beam (Mumm et al., Phys Rev Lett 107:102301, 2011; Chupp et al., Phys Rev C 86:035505, 2012). A non-zero value of D can arise due to parity-even-time-reversal-odd interactions that imply CP violation. Final-state effects also contribute to D at the level of 10 − 5 and can be calculated with precision of 1 % or better. The D coefficient is uniquely sensitive to the imaginary part of the ratio of axial-vector and vector beta-decay amplitudes as well as to scalar and tensor interactions that could arise due to beyond-Standard-Model physics. Over 300 million proton-electron coincidence events were used in a blind analysis with the result D = [ − 0.94±1.89 (stat)±0.97(sys)]×10 − 4. Assuming only vector and axial vector interactions in beta decay, our result can be interpreted as a measure of the phase of the axial-vector coupling relative to the vector coupling, $\phi_{\rm AV}= 180.012^\circ \pm 0.028^\circ$ . This result also improves constrains on certain non-VA interactions.
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- 2013
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21. Precision measurement of the radiative β decay of the free neutron
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Maynard S. Dewey, Hans P. Mumm, T. R. Gentile, Susan Gardner, Robert Cooper, H. Breuer, B O'Neill, Jeffrey S. Nico, Timothy Chupp, Ricardo Alarcon, Kevin J. Coakley, Fred E. Wietfeldt, Daheng He, Matthew J. Bales, J. Byrne, C.D. Bass, Alan K. Thompson, and E. J. Beise
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Photon ,Physics - Instrumentation and Detectors ,Proton ,Physics::Instrumentation and Detectors ,Continuous spectrum ,FOS: Physical sciences ,General Physics and Astronomy ,Photon energy ,7. Clean energy ,01 natural sciences ,Article ,Nuclear physics ,0103 physical sciences ,Radiative transfer ,Neutron ,Nuclear Experiment (nucl-ex) ,010306 general physics ,Nuclear Experiment ,Physics ,010308 nuclear & particles physics ,Branching fraction ,Instrumentation and Detectors (physics.ins-det) ,Photon counting ,High Energy Physics::Experiment ,Atomic physics - Abstract
The standard model predicts that, in addition to a proton, an electron, and an antineutrino, a continuous spectrum of photons is emitted in the $\beta$ decay of the free neutron. We report on the RDK II experiment which measured the photon spectrum using two different detector arrays. An annular array of bismuth germanium oxide scintillators detected photons from 14 to 782~keV. The spectral shape was consistent with theory, and we determined a branching ratio of 0.00335 $\pm$ 0.00005 [stat] $\pm$ 0.00015 [syst]. A second detector array of large area avalanche photodiodes directly detected photons from 0.4 to 14~keV. For this array, the spectral shape was consistent with theory, and the branching ratio was determined to be 0.00582 $\pm$ 0.00023 [stat] $\pm$ 0.00062 [syst]. We report the first precision test of the shape of the photon energy spectrum from neutron radiative decay and a substantially improved determination of the branching ratio over a broad range of photon energies.
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- 2016
22. High-sensitivity measurement ofHe3−He4isotopic ratios for ultracold neutron experiments
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Michael Paul, P. R. Huffman, K. E. Rehm, Liang Yang, R. Scott, R. C. Vondrasek, Michael G. Huber, R. V. F. Janssens, N. Abrams, C.M. O'Shaughnessy, C. Swank, C. L. Jiang, Hans P. Mumm, R. C. Pardo, C.R. Huffer, K.W. Schelhammer, Catherine Deibel, and W. Bauder
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Physics ,Neutron electric dipole moment ,010308 nuclear & particles physics ,Orders of magnitude (temperature) ,chemistry.chemical_element ,Ranging ,Mass spectrometry ,01 natural sciences ,Nuclear physics ,chemistry ,0103 physical sciences ,Neutron ,Sensitivity (control systems) ,010306 general physics ,Helium ,Order of magnitude - Abstract
Research efforts ranging from studies of solid helium to searches for a neutron electric dipole moment require isotopically purified helium with a ratio of ^3He to ^4He at levels below that which can be measured using traditional mass spectroscopy techniques. We demonstrate an approach to such a measurement using accelerator mass spectroscopy, reaching the 10^(−14) level of sensitivity, several orders of magnitude more sensitive than other techniques. Measurements of ^3He/^4He in samples relevant to the measurement of the neutron lifetime indicate the need for substantial corrections. We also argue that there is a clear path forward to sensitivity increases of at least another order of magnitude.
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- 2016
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23. Invited Article: miniTimeCube
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K. Engel, Hans P. Mumm, M. Sakai, J. Murillo, J. Koblanski, S. Negrashov, M. J. Duvall, R. Dorrill, S. Matsuno, V. A. Li, S. A. Wipperfurth, Glenn Jocher, John G. Learned, G. S. Varner, Luca Macchiarulo, S. M. Usman, M. Rosen, William F. McDonough, and K. Nishimura
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Physics ,Physics - Instrumentation and Detectors ,010308 nuclear & particles physics ,business.industry ,Physics::Instrumentation and Detectors ,Detector ,FOS: Physical sciences ,Instrumentation and Detectors (physics.ins-det) ,Scintillator ,01 natural sciences ,Neutron temperature ,Optics ,Neutrino detector ,0103 physical sciences ,Calibration ,NIST ,Neutron ,High Energy Physics::Experiment ,Neutrino ,010306 general physics ,business ,Instrumentation - Abstract
We present the development of the miniTimeCube (mTC), a novel compact neutrino detector. The mTC is a multipurpose detector, aiming to detect not only neutrinos but also fast/thermal neutrons. Potential applications include the counterproliferation of nuclear materials and the investigation of antineutrino short-baseline effects. The mTC is a plastic 0.2% $^{10}$B - doped scintillator (13 cm)$^3$ cube surrounded by 24 Micro-Channel Plate (MCP) photon detectors, each with an $8\times8$ anode totaling 1536 individual channels/pixels viewing the scintillator. It uses custom-made electronics modules which mount on top of the MCPs, making our detector compact and able to both distinguish different types of events and reject noise in real time. The detector is currently deployed and being tested at the National Institute of Standards and Technology (NIST) Center for Neutron Research (NCNR) nuclear reactor (20 MW$_\mathrm{th}$) in Gaithersburg, MD. A shield for further tests is being constructed, and calibration and upgrades are ongoing. The mTC's improved spatiotemporal resolution will allow for determination of incident particle directions beyond previous capabilities., Comment: 19 pages, 29 figures, AIP Review of Scientific Instruments (2016)
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- 2016
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24. A gamma- and X-ray detector for cryogenic, high magnetic field applications
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E. J. Beise, Fred E. Wietfeldt, Alan K. Thompson, K. Pulliam, Ricardo Alarcon, Timothy Chupp, Thomas R. Gentile, Kevin J. Coakley, Matthew J. Bales, C. Fu, C.D. Bass, J. Byrne, B O'Neill, H. Breuer, Maynard S. Dewey, Jeffrey S. Nico, Hans P. Mumm, and Robert Cooper
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Nuclear and High Energy Physics ,Physics - Instrumentation and Detectors ,APDS ,Physics::Instrumentation and Detectors ,Astrophysics::High Energy Astrophysical Phenomena ,X-ray detector ,FOS: Physical sciences ,Superconducting magnet ,Bismuth germanate ,law.invention ,chemistry.chemical_compound ,Optics ,law ,Nuclear Experiment (nucl-ex) ,Nuclear Experiment ,Instrumentation ,Physics ,business.industry ,Detector ,Gamma ray ,Instrumentation and Detectors (physics.ins-det) ,Avalanche photodiode ,Semiconductor detector ,chemistry ,Optoelectronics ,business - Abstract
As part of an experiment to measure the spectrum of photons emitted in beta-decay of the free neutron, we developed and operated a detector consisting of 12 bismuth germanate (BGO) crystals coupled to avalanche photodiodes (APDs). The detector was operated near liquid nitrogen temperature in the bore of a superconducting magnet and registered photons with energies from 5 keV to 1000 keV. To enlarge the detection range, we also directly detected soft X-rays with energies between 0.2 keV and 20 keV with three large area APDs. The construction and operation of the detector are presented, as well as information on operation of APDs at cryogenic temperatures.
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- 2012
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25. Polarized neutron beam properties for measuring parity-violating spin rotation in liquid 4He
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W. M. Snow, Hans P. Mumm, E. I. Sharapov, T. D. Bass, H. E. Swanson, A. Micherdzinska, K. Gan, Jeffrey S. Nico, V. Zhumabekova, D. Luo, A.K. Opper, D. M. Markoff, and C.D. Bass
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Physics ,Nuclear and High Energy Physics ,Astrophysics::High Energy Astrophysical Phenomena ,Nuclear Theory ,Neutron stimulated emission computed tomography ,Polarimeter ,Neutron radiation ,Neutron scattering ,Small-angle neutron scattering ,Neutron time-of-flight scattering ,Nuclear physics ,Neutron cross section ,Neutron ,Nuclear Experiment ,Instrumentation - Abstract
Measurements of parity-violating neutron spin rotation can provide insight into the poorly understood nucleon–nucleon weak interaction. Because the expected rotation angle per unit length is small (10 −7 rad/m), several properties of the polarized cold neutron beam phase space and the neutron optical elements of the polarimeter must be measured to quantify possible systematic effects. This paper presents (1) an analysis of a class of possible systematic uncertainties in neutron spin rotation measurements associated with the neutron polarimetry, and (2) measurements of the relevant neutron beam properties (intensity distribution, energy spectrum, and the product of the neutron beam polarization and the analyzing power as a function of the beam phase space properties) on the NG-6 cold neutron beam-line at the National Institute of Standards and Technology Center for Neutron Research. We conclude that the phase space nonuniformities of the polarimeter in this beam are small enough that a parity-violating neutron spin rotation measurement in n- 4 He with systematic uncertainties at the 10 −7 rad/m level is possible.
- Published
- 2011
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26. Studies of MCP-PMTs in the miniTimeCube neutrino detector
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J. Koblanski, K. Engel, M. Sakai, S. M. Usman, M. Rosen, M. J. Duvall, V. A. Li, Hans P. Mumm, John G. Learned, G. S. Varner, Glenn Jocher, William F. McDonough, S. Negrashov, R. Dorrill, S. Matsuno, K. Nishimura, and S. A. Wipperfurth
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Photomultiplier ,Physics - Instrumentation and Detectors ,FOS: Physical sciences ,General Physics and Astronomy ,Photodetector ,Scintillator ,01 natural sciences ,High Energy Physics - Experiment ,030218 nuclear medicine & medical imaging ,High Energy Physics - Experiment (hep-ex) ,03 medical and health sciences ,0302 clinical medicine ,Optics ,0103 physical sciences ,Physics ,Pixel ,010308 nuclear & particles physics ,business.industry ,Detector ,Instrumentation and Detectors (physics.ins-det) ,lcsh:QC1-999 ,Neutrino detector ,Cube ,Neutrino ,business ,lcsh:Physics - Abstract
This report highlights two different types of cross-talk in the photodetectors of the miniTimeCube neutrino experiment. The miniTimeCube detector has 24 $8 \times 8$-anode Photonis MCP-PMTs Planacon XP85012, totalling 1536 individual pixels viewing the 2-liter cube of plastic scintillator.
- Published
- 2018
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- View/download PDF
27. An experiment for the precision measurement of the radiative decay mode of the neutron
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B. M. Fisher, H. Breuer, Jeffrey S. Nico, Fred E. Wietfeldt, Thomas R. Gentile, Kevin J. Coakley, Timothy Chupp, Maynard S. Dewey, J. Byrne, Robert Cooper, E. J. Beise, C. Fu, M. McGonagle, C.D. Bass, Alan K. Thompson, and Hans P. Mumm
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Physics ,Nuclear and High Energy Physics ,Photon ,Proton ,Physics::Instrumentation and Detectors ,Branching fraction ,Detector ,Photon energy ,Scintillator ,Nuclear physics ,Radiative transfer ,High Energy Physics::Experiment ,Neutron ,Instrumentation - Abstract
The familiar neutron decay into a proton, electron, and antineutrino can be accompanied by photons with sufficient energy to be detected. We recently reported the first observation of the radiative beta decay branch for the free neutron with photons of energy 15–340 keV. We performed the experiment in the bore of a superconducting magnet where electron, proton, and photon signals were measured. A bar of bismuth germanate scintillating crystal coupled to an avalanche photodiode served as the photon detector that operated in the cryogenic, high magnetic field environment. The branching ratio for this energy region was measured and is consistent with the theoretical calculation. An experiment is under way to measure the branching ratio with an improved precision of 1% relative standard uncertainty and to measure the photon energy spectrum. In this paper, the apparatus modifications to reduce the systematic uncertainties will be described. Central to these improvements is the development of a 12-element detector based on the original photon detector design that will improve the statistical sensitivity. During data acquisition, a detailed calibration program will be performed to improve the systematic uncertainties. The development of these modifications is currently under way, and the second run of the experiment commenced in July 2008.
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- 2009
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28. Particle and photon detection for a neutron radiative decay experiment
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T. E. Chupp, Maynard S. Dewey, Fred E. Wietfeldt, Thomas R. Gentile, Alan K. Thompson, Isaac Kremsky, K G. Kiriluk, B. M. Fisher, Robert Cooper, Jeffrey S. Nico, Hans P. Mumm, and E. J. Beise
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Physics ,Nuclear and High Energy Physics ,Physics::Instrumentation and Detectors ,Scintillator ,Avalanche photodiode ,Bismuth germanate ,Particle detector ,Semiconductor detector ,Photodiode ,law.invention ,Nuclear physics ,chemistry.chemical_compound ,chemistry ,law ,Neutron detection ,Neutron ,Instrumentation - Abstract
We present the particle and photon detection methods employed in a program to observe neutron radiative beta-decay. The experiment is located at the NG-6 beam line at the National Institute of Standards and Technology Center for Neutron Research. Electrons and protons are guided by a 4.6 T magnetic field and detected by a silicon surface barrier detector. Photons with energies between 15 and 750 keV are registered by a detector consisting of a bismuth germanate scintillator coupled to a large area avalanche photodiode. The photon detector operates at a temperature near 80 K in the bore of a superconducting magnet. We discuss CsI as an alternative scintillator, and avalanche photodiodes for direct detection of photons in the 0.1–10 keV range.
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- 2007
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29. The PROSPECT Physics Program
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Minfang Yeh, M. P. Green, R. Neilson, X. Zhang, Wei Wang, Lindsey J. Bignell, D. J. Dean, Christopher G. White, R. L. Varner, J. P. Brodsky, Michael Febbraro, Hans P. Mumm, G. Barclay, T. J. Langford, Steven Sheets, A. Bowes, H. R. Band, B. R. White, C. Trinh, C.D. Bass, B. Viren, D. E. Jaffe, K. M. Heeger, D. A. Martinez Caicedo, Richard Rosero, J. Ashenfelter, B. Heffron, D. Norcini, J. Dolph, K. Commeford, Nathaniel Bowden, Ke Han, Chao Zhang, B. Seilhan, Dmitry A. Pushin, J. Wilhelmi, A. J. Conant, D. C. Jones, J. Insler, A. B. Balantekin, Xin Qian, M. J. Dolinski, E. Romero, S. Hans, C. D. Bryan, Jim Napolitano, T. Classen, G. Zangakis, B. W. Goddard, R. Sharma, J. K. Gaison, J. J. Cherwinka, K. Gilje, G. Deichert, Y-R Yen, A. Glenn, M. V. Diwan, D. Davee, M DuVernois, P. E. Mueller, Christopher B. Williams, J. T. Matta, H. Yao, Rui-Lin Chu, Anna Erickson, T. Wise, D. Berish, B. Hackett, A. Galindo-Uribarri, B. R. Littlejohn, J. Nikkel, P. T. Surukuchi, M P Mendenhall, and R D McKeown
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Physics ,Nuclear and High Energy Physics ,Sterile neutrino ,Physics - Instrumentation and Detectors ,010308 nuclear & particles physics ,Detector ,FOS: Physical sciences ,Instrumentation and Detectors (physics.ins-det) ,Scintillator ,Parameter space ,01 natural sciences ,Physics::Geophysics ,High Energy Physics - Experiment ,Nuclear physics ,High Energy Physics - Experiment (hep-ex) ,Nuclear reactor core ,Inverse beta decay ,0103 physical sciences ,High Energy Physics::Experiment ,Nuclear Experiment (nucl-ex) ,Neutrino ,010306 general physics ,Neutrino oscillation ,Nuclear Experiment - Abstract
The Precision Reactor Oscillation and Spectrum Experiment, PROSPECT, is designed to make a precise measurement of the antineutrino spectrum from a highly-enriched uranium reactor and probe eV-scale sterile neutrinos by searching for neutrino oscillations over meter-long distances. PROSPECT is conceived as a 2-phase experiment utilizing segmented $^6$Li-doped liquid scintillator detectors for both efficient detection of reactor antineutrinos through the inverse beta decay reaction and excellent background discrimination. PROSPECT Phase I consists of a movable 3-ton antineutrino detector at distances of 7 - 12 m from the reactor core. It will probe the best-fit point of the $\nu_e$ disappearance experiments at 4$\sigma$ in 1 year and the favored region of the sterile neutrino parameter space at $>$3$\sigma$ in 3 years. With a second antineutrino detector at 15 - 19 m from the reactor, Phase II of PROSPECT can probe the entire allowed parameter space below 10 eV$^{2}$ at 5$\sigma$ in 3 additional years. The measurement of the reactor antineutrino spectrum and the search for short-baseline oscillations with PROSPECT will test the origin of the spectral deviations observed in recent $\theta_{13}$ experiments, search for sterile neutrinos, and conclusively address the hypothesis of sterile neutrinos as an explanation of the reactor anomaly., Comment: 21 pages, 21 figures
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- 2015
30. Light collection and pulse-shape discrimination in elongated scintillator cells for the PROSPECT reactor antineutrino experiment
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E. Romero, Chao Zhang, M. P. Mendenhall, J. J. Cherwinka, K. Gilje, H. Yao, A. Galindo-Uribarri, B. R. Littlejohn, Christopher B. Williams, J. Ashenfelter, X. Zhang, D. J. Dean, A. Bowes, Minfang Yeh, P. T. Surukuchi, H. R. Band, N.T. Stemen, J. K. Gaison, B. R. White, R. Sharma, M. V. Diwan, D. E. Jaffe, D. Davee, Rui-Lin Chu, D. A. Martinez Caicedo, C. D. Bryan, Xin Qian, Y-R Yen, L. Saldaña, G. Deichert, R. D. McKeown, B. Balantekin, C. White, G. Zangakis, A. Glenn, J. Wilhelmi, G. Barclay, B. W. Goddard, T. Wise, D. Berish, B. Viren, R. L. Varner, D. A. Dwyer, K. Commeford, T. J. Langford, Steven Sheets, R. Rosero, Jim Napolitano, S. Hans, Ke Han, D. Norcini, B. Heffron, Wei Wang, Nathaniel Bowden, R. Neilson, J. P. Brodsky, J. Dolph, M. J. Dolinski, Hans P. Mumm, T. Classen, C.D. Bass, K. M. Heeger, M. P. Green, B. Seilhan, Dmitry A. Pushin, and P. E. Mueller
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Physics - Instrumentation and Detectors ,FOS: Physical sciences ,Scintillator ,High Energy Physics - Experiment ,High Energy Physics - Experiment (hep-ex) ,Particle identification methods ,Calorimeters ,Optics ,Engineering ,Calibration ,Neutron ,Neutrino detectors ,Nuclear Experiment ,Instrumentation ,Mathematical Physics ,Spontaneous fission ,Physics ,Range (particle radiation) ,Reflector (photography) ,business.industry ,Detector ,Instrumentation and Detectors (physics.ins-det) ,Nuclear & Particles Physics ,Other Physical Sciences ,Inverse beta decay ,Physical Sciences ,business - Abstract
A meter-long, 23-liter EJ-309 liquid scintillator detector has been constructed to study the light collection and pulse-shape discrimination performance of elongated scintillator cells for the PROSPECT reactor antineutrino experiment. The magnitude and uniformity of light collection and neutron/gamma discrimination power in the energy range of antineutrino inverse beta decay products have been studied using gamma and spontaneous fission calibration sources deployed along the cell long axis. We also study neutron-gamma discrimination and light collection abilities for differing PMT and reflector configurations. Key design features for optimizing MeV-scale response and background rejection capabilities are identified., Comment: 20 pages, 11 figures
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- 2015
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31. Searches for Exotic Spin-Dependent Interactions of Slow Neutrons with Matter using Neutron Spin Rotation
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D.M. Markoff, Swadeshmukul Santra, J. Fry, H. Gardiner, B.E. Crawford, S. van Sciver, Hans P. Mumm, C.D. Bass, Aaron Sprow, J. Lieffers, C. Crawford, C. Paudel, J. Vanderwerp, L. Barron Palos, C. Haddock, Blayne Heckel, D. Esposito, S. D. Penn, W. M. Snow, A. T. Holley, R.C. Malone, W. Fox, M. Maldonado-Velázquez, D. Olek, E. Anderson, P.C. Rout, H.E. Swanson, M. Sarsour, and Jeffrey S. Nico
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Physics ,Nuclear physics ,Particle physics ,Liquid helium ,law ,Neutron ,Nuclear Experiment ,Upper and lower bounds ,Boson ,law.invention - Abstract
Polarized slow neutrons can be used to conduct sensitive searches for subtle spin-dependent neutron interactions in matter. A brief overview of the theoretical context in which such searches are important is given. We present the result of a recent measurement of neutron spin rotation in liquid helium that constrains possible exotic long-range parity-odd interactions between the neutron and matter from the exchange of spin 1 bosons of meV-scale masses. The experiment also places the first upper bound to our knowledge on what may be called “in-matter”gravitational torsion. Finally, we discuss a proposed search for a possible parity-even exotic interaction of polarized neutrons with matter from spin 1 boson exchange with axial couplings for boson masses in the meV range.
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- 2015
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32. Background Radiation Measurements at High Power Research Reactors
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S. Morrell, H. Yao, D. Davee, Ke Han, N.T. Stemen, Rui-Lin Chu, Christopher B. Williams, C.D. Bass, D. Martinez, R. L. Varner, Chao Zhang, S. H. Kettell, D. A. Dwyer, T. J. Langford, T. Classen, B. Balantekin, Minfang Yeh, Wei Wang, J. Dolph, J. Ashenfelter, Nathaniel Bowden, B. Heffron, G. Barclay, Hans P. Mumm, G. Deichert, M. P. Green, J. Wilhelmi, K. M. Heeger, T. Wise, H. R. Band, D. Berish, E. Romero, Y-R Yen, X. Zhang, Scott M. Watson, M. J. Dolinski, D. Norcini, Richard Rosero, C. Baldenegro, A. Glenn, A. Galindo-Uribarri, B. R. Littlejohn, L. Saldaña, B. Seilhan, Dmitry A. Pushin, P. T. Surukuchi, P. E. Mueller, D. J. Dean, Jim Napolitano, J.K. Gaison, R. D. McKeown, D. E. Jaffe, Christopher G. White, B. R. White, S. Fan, R. Sharma, J. J. Cherwinka, K. Gilje, Scott J. Thompson, S. Hans, and C. D. Bryan
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Nuclear and High Energy Physics ,Physics - Instrumentation and Detectors ,Nuclear engineering ,FOS: Physical sciences ,Atomic ,01 natural sciences ,Background measurements ,law.invention ,High Energy Physics - Experiment ,Nuclear physics ,High Energy Physics - Experiment (hep-ex) ,Particle and Plasma Physics ,law ,Neutron flux ,0103 physical sciences ,Nuclear ,Neutron ,Nuclear Experiment (nucl-ex) ,010306 general physics ,Instrumentation ,Nuclear Experiment ,Background radiation ,Physics ,010308 nuclear & particles physics ,technology, industry, and agriculture ,Molecular ,Instrumentation and Detectors (physics.ins-det) ,Nuclear reactor ,Reactor antineutrino detection ,Nuclear & Particles Physics ,Other Physical Sciences ,Radiation flux ,Research reactors ,Astronomical and Space Sciences - Abstract
Research reactors host a wide range of activities that make use of the intense neutron fluxes generated at these facilities. Recent interest in performing measurements with relatively low event rates, e.g. reactor antineutrino detection, at these facilities necessitates a detailed understanding of background radiation fields. Both reactor-correlated and naturally occurring background sources are potentially important, even at levels well below those of importance for typical activities. Here we describe a comprehensive series of background assessments at three high-power research reactors, including $\gamma$-ray, neutron, and muon measurements. For each facility we describe the characteristics and identify the sources of the background fields encountered. The general understanding gained of background production mechanisms and their relationship to facility features will prove valuable for the planning of any sensitive measurement conducted therein., Comment: 26 pages, 28 figures. Accepted for publication in Nuclear Instruments and Methods A. v2 incorporates minor revisions requested by NIMA
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- 2015
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33. Measuring the Neutron Lifetime with Magnetically Trapped Ultracold Neutrons
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C.M. O'Shaughnessy, P. R. Huffman, A. T. Yue, Michael G. Huber, K.W. Schelhammer, Kevin J. Coakley, C.R. Huffer, Hans P. Mumm, Maynard S. Dewey, and Alan K. Thompson
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Physics ,Nuclear physics ,Ultracold neutrons ,Neutron - Published
- 2014
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34. Time reversal in polarized neutron decay: the emiT experiment
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Gordon L. Jones, Fred E. Wietfeldt, B. K. Fujikawa, E. G. Wasserman, Hans P. Mumm, S. R. Hwang, Juan-Manuel Anaya, Timothy Chupp, A. Garcia, W. A. Teasdale, J. M. Adams, G. L. Greene, R. G. H. Robertson, Jeffrey S. Nico, Kevin P. Coulter, T. D. Steiger, L. J. Lising, Stuart Freedman, Alan K. Thompson, Maynard S. Dewey, J. F. Wilkerson, and T. J. Bowles
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Physics ,Nuclear and High Energy Physics ,Particle physics ,Physics beyond the Standard Model ,Weak interaction ,Nuclear physics ,Double beta decay ,High Energy Physics::Experiment ,Neutron ,Positron emission ,Neutrino ,Nucleon ,Instrumentation ,Radioactive decay - Abstract
The standard electro-weak model predicts negligible violation of time-reversal invariance in light quark processes. We report on an experimental test of time-reversal invariance in the beta decay of polarized neutrons as a search for physics beyond the standard model. The emiT collaboration has measured the time-reversal-violating triple-correlation in neutron beta decay between the neutron spin, electron momentum, and neutrino momentum often referred to as the D coe$cient. The "rst run of the experiment produced 14 million events which are currently being analyzed. However, a second run with improved detectors should provide greater statistical precision and reduced systematic uncertainties. ( 2000 Elsevier Science B.V. All rights reserved.
- Published
- 2000
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35. Search for aT-odd,P-even triple correlation in neutron decay
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A. Garcia, Hans P. Mumm, B. K. Fujikawa, Kevin P. Coulter, Jeffrey S. Nico, Fred E. Wietfeldt, Robert Cooper, Alan K. Thompson, J. F. Wilkerson, Timothy Chupp, Gordon L. Jones, Stuart J. Freedman, and C. Trull
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Quantum chromodynamics ,Physics ,Nuclear and High Energy Physics ,Muon ,010308 nuclear & particles physics ,CPT symmetry ,Cabibbo–Kobayashi–Maskawa matrix ,Physics beyond the Standard Model ,media_common.quotation_subject ,01 natural sciences ,Asymmetry ,Nuclear physics ,0103 physical sciences ,CP violation ,Leptoquark ,010306 general physics ,media_common - Abstract
Search for a T-odd, P-even Triple Correlation in Neutron Decay T.E. Chupp, 1 R.L. Cooper, 1 K.P. Coulter, 1 S.J. Freedman, 2 B.K. Fujikawa, 2 A. Garc´ia, 3, 4 G.L. Jones, 5 H.P. Mumm, 6 J.S. Nico, 6 A.K. Thompson, 6 C.A. Trull, 7 F.E. Wietfeldt, 7 and J.F. Wilkerson 3, 8, 9 University of Michigan, Ann Arbor, Michigan 48104, USA Physics Department, University of California, Berkeley, and Lawrence Berkeley National Laboratory, Berkeley, California 94720, USA CENPA and Physics Department, University of Washington, Seattle, WA 98195 USA Department of Physics, University of Notre Dame, Notre Dame, IN 46556 USA Physics Department, Hamilton College, Clinton, NY 13323, USA National Institute of Standards and Technology, Gaithersburg, MD 20899, USA Physics Department, Tulane University, New Orleans, LA 70118, USA Department of Physics and Astronomy, University of North Carolina, Chapel Hill, North Carolina 27599, USA Oak Ridge National Lab, Oak Ridge, TN, 37831 USA Background: Time-reversal-invariance violation, or equivalently CP violation, may explain the observed cosmological baryon asymmetry as well as signal physics beyond the Standard Model. In the decay of polarized neutrons, the triple correlation D J n ·(p e ×p ν ) is a parity-even, time-reversal- odd observable that is uniquely sensitive to the relative phase of the axial-vector amplitude with respect to the vector amplitude. The triple correlation is also sensitive to possible contributions from scalar and tensor amplitudes. Final-state effects also contribute to D at the level of 10 −5 and can be calculated with a precision of 1% or better. Purpose: We have improved the sensitivity to T-odd, P-even interactions in nuclear beta decay. Methods: We measured proton-electron coincidences from decays of longitudinally polarized neutrons with a highly symmetric detector array designed to cancel the time-reversal-even, parity-odd Standard-Model contributions to polarized neutron decay. Over 300 million proton-electron coincidence events were used to extract D and study systematic effects in a blind analysis. Results: We find D = [−0.94 ± 1.89(stat) ± 0.97(sys)] × 10 −4 . Conclusions: This is the most sensitive measurement of D in nuclear beta decay. Our result can be interpreted as a measurement of the phase of the ratio of the axial-vector and vector coupling constants (C A /C V = |λ|e iφ AV ) with φ AV = 180.012 ◦ ±0.028 ◦ (68% confidence level) or to constrain time-reversal violating scalar and tensor interactions that arise in certain extensions to the Standard Model such as leptoquarks. This paper presents details of the experiment, analysis, and systematic- error corrections. PACS numbers: 24.80.+y, 11.30.Er, 12.15.Ji, 13.30.Ce DISCLAIMER: This document was prepared as an account of work sponsored by the United States Government. While this document is believed to contain correct information, neither the United States Government nor any agency thereof, nor the Regents of the University of Cal- ifornia, nor any of their employees, makes any warranty, express or implied, or assumes any le- gal responsibility for the accuracy, completeness, or usefulness of any information, apparatus, prod- uct, or process disclosed, or represents that its use would not infringe privately owned rights. Refer- ence herein to any specific commercial product, process, or service by its trade name, trademark, manufacturer, or otherwise, does not necessarily constitute or imply its endorsement, recommen- dation, or favoring by the United States Govern- ment or any agency thereof, or the Regents of the University of California. The views and opin- ions of authors expressed herein do not necessar- ily state or reflect those of the United States Gov- ernment or any agency thereof or the Regents of the University of California. I. INTRODUCTION The symmetries of physical processes under the trans- formations of charge conjugation (C), parity (P), and time reversal (T) have played a central role in the de- velopment of the Standard Model of elementary-particle interactions [1]. Time-reversal-symmetry violation (or T violation), which is equivalent to CP violation assum- ing CPT symmetry, has been of particular interest be- cause it is sensitive to many kinds of new physics. The CP-violating parameters of the Standard Model are the Cabibbo-Kobayashi-Maskawa (CKM) phase, which en- ters in the mixing of three generations of quarks, and the parameter θ QCD . The effect of the CKM phase is strongly suppressed in the permanent electric dipole mo- ments (EDMs) of the neutron [2] and heavy atoms [3, 4], and recent EDM results combine to set upper limits on θ QCD . All laboratory measurements to date are consis- tent with a single source of CP violation, i.e. the phase in the CKM matrix. An exception may be the 3.2 sigma deviation observed recently as an asymmetry in the pro- duction of pairs of like-sign muons reported by the D0
- Published
- 2012
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36. A New Limit on Time-Reversal-Invariance Violation in Beta Decay: Results of the emiT-II Experiment
- Author
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Hans P. Mumm
- Subjects
Physics ,Particle physics ,Limit (mathematics) ,Beta decay - Published
- 2012
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- View/download PDF
37. Experimental Parameters for a Reactor Antineutrino Experiment at Very Short Baselines
- Author
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Hans P. Mumm, K. M. Heeger, B. R. Littlejohn, and M. N. Tobin
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Physics ,Nuclear and High Energy Physics ,Sterile neutrino ,Particle physics ,Nuclear fission product ,Oscillation ,Solar neutrino ,FOS: Physical sciences ,Solar neutrino problem ,High Energy Physics - Experiment ,Physics::Geophysics ,Nuclear physics ,High Energy Physics - Experiment (hep-ex) ,Research reactor ,High Energy Physics::Experiment ,Neutrino ,Physics::Chemical Physics ,Nuclear Experiment (nucl-ex) ,Neutrino oscillation ,Nuclear Experiment - Abstract
Reactor antineutrinos are used to study neutrino oscillation, search for signatures of non-standard neutrino interactions, and to monitor reactor operation for safeguard applications. The flux and energy spectrum of reactor antineutrinos can be predicted from the decays of the nuclear fission products. A comparison of recent reactor calculations with past measurements at baselines of 10-100m suggests a 5.7% deficit. Precision measurements of reactor antineutrinos at very short baselines O(1-10 m) can be used to probe this anomaly and search for possible oscillations into sterile neutrino species. This paper studies the experimental requirements for a new reactor antineutrino measurement at very short baselines and calculates the sensitivity of various scenarios. We conclude that an experiment at a typical research reactor provides 5{\sigma} discovery potential for the favored oscillation parameter space with 3 years of data collection., Comment: 22 pages, 18 figures, 4 tables
- Published
- 2012
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- View/download PDF
38. A new limit on time-reversal violation in beta decay: Results of the emiTII experiment
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Alan K. Thompson, J. F. Wilkerson, B. J. Fujikawa, C. Trull, Hans P. Mumm, Fred E. Wietfeldt, A. Garcia, Kevin P. Coulter, Robert Cooper, Gordon L. Jones, Stuart J. Freedman, Timothy Chupp, and Jeffrey S. Nico
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Physics ,Nuclear physics ,Quark ,Particle physics ,CPT symmetry ,Scalar (mathematics) ,CP violation ,High Energy Physics::Experiment ,Neutron ,Tensor ,Triple correlation ,Coincidence - Abstract
We have measured the triple correlation D〈Jn〉 · (pe × pv) with a polarized cold-neutron beam at the NIST Center for Neutron Research by observing proton-electron coincidences in the decay of polarized neutrons. A non-zero value of D can arise due to parity-even-time-reversal-odd interactions that imply CP violation due to the CPT theorem. Final-state effects also contribute to D at the level of 10−5 and can be calculated with precision of 1% or better. The D coefficient is sensitive to the phase, of λ the ratio of axial-vector and vector amplitudes as well as to scalar and tensor interactions that could arise due to beyond-Standard-Model physics such as leptoquarks. Over 300 million proton-electron coincidence events were used in a blind analysis with the result D = [−0.96±1.89(stat)±1.01(sys)]×10−4.
- Published
- 2012
- Full Text
- View/download PDF
39. New Limit on Time-Reversal Violation in Beta Decay
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Fred E. Wietfeldt, Gordon L. Jones, Robert Cooper, B. K. Fujikawa, Timothy Chupp, C. Trull, A. Garcia, Jeffrey S. Nico, J. F. Wilkerson, Stuart J. Freedman, Hans P. Mumm, Alan K. Thompson, and Kevin P. Coulter
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Physics ,Hadron ,Center (category theory) ,FOS: Physical sciences ,General Physics and Astronomy ,Elementary particle ,Beta decay ,Baryon ,Nuclear physics ,High Energy Physics::Experiment ,Neutron ,Nuclear Experiment (nucl-ex) ,Atomic physics ,Nucleon ,Nuclear Experiment ,Radioactive decay - Abstract
We report the results of an improved determination of the triple correlation $D P \cdot(p_{e}\times p_{\nu})$ that can be used to limit possible time-reversal invariance in the beta decay of polarized neutrons and constrain extensions to the Standard Model. Our result is $D=(-0.96\pm 1.89 (stat)\pm 1.01 (sys))\times 10^{-4}$. The corresponding phase between g_A and g_V is $\phi_{AV} = 180.013^\circ\pm0.028^\circ$ (68 % confidence level). This result represents the most sensitive measurement of D in beta decay., Comment: 4 pages, 4 figures Fixed typos, a Ref., and Fig. 1
- Published
- 2011
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40. Upper bound on parity-violating neutron spin rotation inHe4
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A.K. Opper, K. Gan, M. Sarsour, C.D. Bass, Bret E. Crawford, S. B. Walbridge, T. D. Bass, D. M. Markoff, Jeffrey S. Nico, Blayne Heckel, V. Zhumabekova, E. I. Sharapov, W. M. Snow, Hans P. Mumm, H. E. Swanson, A. M. Micherdzinska, and D. Luo
- Subjects
Physics ,Baryon ,Nuclear and High Energy Physics ,Particle physics ,Helium-4 ,Hadron ,Elementary particle ,Neutron ,Atomic physics ,Nuclear Experiment ,Nucleon ,Spin (physics) ,Isotopes of helium - Abstract
We report an upper bound on parity-violating neutron spin rotation in $^{4}\mathrm{He}$. This experiment is the most sensitive search for neutron-weak optical activity yet performed and represents a significant advance in precision in comparison to past measurements in heavy nuclei. The experiment was performed at the NG-6 slow-neutron beamline at the National Institute of Standards and Technology (NIST) Center for Neutron Research. Our result for the neutron spin rotation angle per unit length in $^{4}\mathrm{He}$ is $d\ensuremath{\phi}/\mathit{dz}=[+1.7\ifmmode\pm\else\textpm\fi{}9.1(\text{stat.})\ifmmode\pm\else\textpm\fi{}1.4(\text{sys.})]\ifmmode\times\else\texttimes\fi{}{10}^{\ensuremath{-}7}$ rad/m. The statistical uncertainty is smaller than current estimates of the range of possible values of $d\ensuremath{\phi}/\mathit{dz}$ in $n{+}^{4}$He.
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- 2011
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41. Radiativeβdecay of the free neutron
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Robert Cooper, Timothy Chupp, B. M. Fisher, E. J. Beise, Isaac Kremsky, J. Byrne, Thomas R. Gentile, Kevin J. Coakley, Hans P. Mumm, K G. Kiriluk, Fred E. Wietfeldt, Changbo Fu, Alan K. Thompson, Maynard S. Dewey, and Jeffrey S. Nico
- Subjects
Physics ,Nuclear and High Energy Physics ,Decay scheme ,Branching fraction ,Beta-decay stable isobars ,Nuclear physics ,Particle decay ,Internal conversion ,Double beta decay ,High Energy Physics::Experiment ,Neutron ,Atomic physics ,Nuclear Experiment ,Radioactive decay - Abstract
The theory of quantum electrodynamics predicts that the $\ensuremath{\beta}$ decay of the neutron into a proton, electron, and antineutrino is accompanied by a continuous spectrum of emitted photons described as inner bremsstrahlung. While this phenomenon has been observed in nuclear $\ensuremath{\beta}$ decay and electron-capture decay for many years, it has only been recently observed in free-neutron decay. We present a detailed discussion of an experiment in which the radiative decay mode of the free neutron was observed. In this experiment, the branching ratio for this rare decay was determined by recording photons that were correlated with both the electron and proton emitted in neutron decay. We determined the branching ratio for photons with energy between 15 and 340 keV to be $(3.09\ifmmode\pm\else\textpm\fi{}0.32)\ifmmode\times\else\texttimes\fi{}{10}^{\ensuremath{-}3}$ (68% level of confidence), where the uncertainty is dominated by systematic effects. This value for the branching ratio is consistent with theoretical predictions. The characteristic energy spectrum of the radiated photons, which differs from the uncorrelated background spectrum, is also consistent with the theoretical spectrum.
- Published
- 2010
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42. Measuring the Neutron Lifetime Using Magnetically Trapped Neutrons
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C. E. H. Mattoni, S. N. Dzhosyuk, Daniel McKinsey, John M. Doyle, Robert Golub, P.-N. Seo, Kevin J. Coakley, P. R. Huffman, G. Yang, Steve K. Lamoreaux, C. M. O’Shaughnessy, Liang Yang, Alan K. Thompson, Hans P. Mumm, K.W. Schelhammer, and C. Swank
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Physics ,Condensed Matter::Quantum Gases ,Nuclear and High Energy Physics ,010308 nuclear & particles physics ,Neutron emission ,FOS: Physical sciences ,Neutron scattering ,7. Clean energy ,01 natural sciences ,Neutron temperature ,Nuclear physics ,Neutron flux ,0103 physical sciences ,Neutron cross section ,Ultracold neutrons ,Neutron detection ,Neutron ,Physics::Atomic Physics ,Nuclear Experiment (nucl-ex) ,Atomic physics ,010306 general physics ,Nuclear Experiment ,Instrumentation - Abstract
The neutron beta-decay lifetime plays an important role both in understanding weak interactions within the framework of the Standard Model and in theoretical predictions of the primordial abundance of 4He in Big Bang Nucleosynthesis. In previous work, we successfully demonstrated the trapping of ultracold neutrons (UCN) in a conservative potential magnetic trap. A major upgrade of the apparatus is nearing completion at the National Institute of Standards and Technology Center for Neutron Research (NCNR). In our approach, a beam of 0.89 nm neutrons is incident on a superfluid 4He target within the minimum field region of an Ioffe-type magnetic trap. A fraction of the neutrons is downscattered in the helium to energies, 5 pages, 5 figures
- Published
- 2009
43. A slow neutron polarimeter for the measurement of parity-odd neutron rotary power
- Author
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J. M. Dawkins, L. Barrón-Palos, D. M. Markoff, Hans P. Mumm, D. Esposito, J. C. Horton, W. M. Snow, C.R. Huffer, A. T. Holley, Swadeshmukul Santra, A. M. Micherdzinska, M. Sarsour, J. Lieffers, Christopher Crawford, C. Haddock, E. I. Sharapov, M. Maldonado-Velázquez, J. Fry, K. Gan, V. Zhumabekova, Blayne Heckel, T. D. Bass, E. Anderson, H. E. Swanson, Jeffrey S. Nico, C.D. Bass, Bret E. Crawford, S. B. Walbridge, D. Luo, and H. Gardiner
- Subjects
Physics ,Bonner sphere ,business.industry ,Astrophysics::High Energy Astrophysical Phenomena ,Polarimeter ,Polarizer ,Polarization (waves) ,Neutron time-of-flight scattering ,law.invention ,Nuclear physics ,Optics ,law ,Neutron source ,Neutron detection ,Neutron ,Nuclear Experiment ,business ,Instrumentation - Abstract
We present the design, description, calibration procedure, and an analysis of systematic effects for an apparatus designed to measure the rotation of the plane of polarization of a transversely polarized slow neutron beam as it passes through unpolarized matter. This device is the neutron optical equivalent of a crossed polarizer/analyzer pair familiar from light optics. This apparatus has been used to search for parity violation in the interaction of polarized slow neutrons in matter. Given the brightness of existing slow neutron sources, this apparatus is capable of measuring a neutron rotary power of dϕ/dz = 1 × 10(-7) rad/m.
- Published
- 2015
- Full Text
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44. Progress Towards a Precision Measurement of the Neutron Lifetime Using Magnetically Trapped Ultracold Neutrons
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Robert Golub, P. R. Huffman, Steve K. Lamoreaux, E. Korobkina, John M. Doyle, Hans P. Mumm, F.H. DuBose, Liang Yang, Alan K. Thompson, Kevin J. Coakley, G. Yang, G. R. Palmquist, P.-N. Seo, and C. M. O’Shaughnessy
- Subjects
Condensed Matter::Quantum Gases ,Physics ,Physics::Instrumentation and Detectors ,Electron ,Inelastic scattering ,Nuclear physics ,Helium-4 ,Magnetic trap ,Ultracold neutrons ,Neutron ,Physics::Atomic Physics ,Atomic physics ,Nuclear Experiment ,Isotopes of helium ,Superfluid helium-4 - Abstract
As part of an on‐going program utilizing magnetically trapped ultracold neutrons (UCNs), we are developing a technique that offers the possibility of improving the precision of the neutron lifetime by more than an order of magnitude. The experiment works by loading an Ioffe‐type superconducting magnetic trap with UCNs through inelastic scattering of 0.89 nm neutrons with phonons in superfluid 4He. Trapped neutrons are detected when they decay; charged decay electrons ionize helium atoms in the superfluid resulting in scintillation light that is recorded in real time using photomultiplier tubes. At present, we are installing a larger and deeper superconducting magnetic trap into our apparatus, implementing techniques to reduce background events, and working to increase the neutron decay detection efficiency. We report the status of the construction of the improved apparatus.
- Published
- 2006
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45. Measurement of the Parity-Violating Neutron Spin Rotation in (4) He
- Author
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P. R. Huffman, J. M. Dawkins, C.D. Bass, B. R. Heckel, M Sarsour, D. Luo, H.E. Swanson, W. M. Snow, D. M. Markoff, Jeffrey S. Nico, Hans P. Mumm, and A. M. Micherdzinska
- Subjects
Physics ,Spin polarization ,Meson ,liquid helium ,Liquid helium ,Nuclear Theory ,spin rotation ,superfluid helium ,General Engineering ,Parity (physics) ,Weak interaction ,cold neutrons ,Article ,law.invention ,Nuclear physics ,weak interaction ,law ,Isospin ,nucleon-nucleon interaction ,Neutron ,weak meson exchange amplitude ,Nucleon ,Nuclear Experiment ,parity non-conservation ,parity violation - Abstract
In the meson exchange model of weak nucleon-nucleon (NN) interactions, the exchange of virtual mesons between the nucleons is parameterized by a set of weak meson exchange amplitudes. The strengths of these amplitudes from theoretical calculations are not well known, and experimental measurements of parity-violating (PV) observables in different nuclear systems have not constrained their values. Transversely polarized cold neutrons traveling through liquid helium experience a PV spin rotation due to the weak interaction with an angle proportional to a linear combination of these weak meson exchange amplitudes. A measurement of the PV neutron spin rotation in helium (φ PV ( n ,α)) would provide information about the relative strengths of the weak meson exchange amplitudes, and with the longitudinal analyzing power measurement in the p + α system, allow the first comparison between isospin mirror systems in weak NN interaction. An earlier experiment performed at NIST obtained a result consistent with zero: φ PV ( n ,α) = (8.0 ±14(stat) ±2.2(syst)) ×10(-7) rad / m[1]. We describe a modified apparatus using a superfluid helium target to increase statistics and reduce systematic effects in an effort to reach a sensitivity goal of 10(-7) rad/m.
- Published
- 2005
46. emiT: an apparatus to test time reversal invariance in polarized neutron decay
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Alan K. Thompson, Stuart J. Freedman, Fred E. Wietfeldt, B. K. Fujikawa, L. J. Lising, K. M. Sundqvist, Robert Cooper, Robert C. Welsh, C. Trull, Hans P. Mumm, S. R. Hwang, Maynard S. Dewey, T. E. Chupp, L. Grout, Leah Broussard, Kevin P. Coulter, Jeffrey S. Nico, Alejandro Garcia, L. P. Parazzoli, Gordon L. Jones, M. A. Howe, J. F. Wilkerson, and R. G. H. Robertson
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Physics ,Proton ,Physics::Instrumentation and Detectors ,Detector ,FOS: Physical sciences ,Electron ,Neutron radiation ,Scintillator ,Coincident ,Neutron ,High Energy Physics::Experiment ,Atomic physics ,Nuclear Experiment (nucl-ex) ,Nuclear Experiment ,Instrumentation ,Diode - Abstract
We describe an apparatus used to measure the triple-correlation term (\D \hat{\sigma}_n\cdot p_e\times p_\nu) in the beta-decay of polarized neutrons. The \D-coefficient is sensitive to possible violations of time reversal invariance. The detector has an octagonal symmetry that optimizes electron-proton coincidence rates and reduces systematic effects. A beam of longitudinally polarized cold neutrons passes through the detector chamber, where a small fraction beta-decay. The final-state protons are accelerated and focused onto arrays of cooled semiconductor diodes, while the coincident electrons are detected using panels of plastic scintillator. Details regarding the design and performance of the proton detectors, beta detectors and the electronics used in the data collection system are presented. The neutron beam characteristics, the spin-transport magnetic fields, and polarization measurements are also described., Comment: 15 pages, 13 figures
- Published
- 2004
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- View/download PDF
47. New Limit on the D Coefficient in Polarized Neutron Decay
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Robert C. Welsh, J. M. Richardson, Fred E. Wietfeldt, B. K. Fujikawa, E. G. Wasserman, S. R. Hwang, J. M. Adams, R. G. H. Robertson, W. A. Teasdale, Kevin P. Coulter, M. C. Browne, Timothy Chupp, Alan K. Thompson, Maynard S. Dewey, Hans P. Mumm, A. Garcia, G. L. Greene, Stuart J. Freedman, Gordon L. Jones, L. J. Lising, Jeffrey S. Nico, T. D. Steiger, J. F. Wilkerson, and T. J. Bowles
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Physics ,Nuclear and High Energy Physics ,Particle physics ,Hadron ,FOS: Physical sciences ,Elementary particle ,Fermion ,Baryon ,Particle decay ,CP violation ,Leptoquark ,High Energy Physics::Experiment ,Nuclear Experiment (nucl-ex) ,Nucleon ,Nuclear Experiment - Abstract
We describe an experiment that has set new limits on the time reversal invariance violating D coefficient in neutron beta-decay. The emiT experiment measured the angular correlation J . p_e x p_p using an octagonal symmetry that optimizes electron-proton coincidence rates. The result is D=[-0.6+/-1.2(stat)+/-0.5(syst)]x10^(-3). This improves constraints on the phase of g_A/g_V and limits contributions to T violation due to leptoquarks. This paper presents details of the experiment, data analysis, and the investigation of systematic effects., Comment: The emiT collaboration. 11 pages, 14 figures. Submitted to Physical Review C
- Published
- 2000
- Full Text
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48. Invited Article: Development of high-field superconducting Ioffe magnetic traps
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Alan K. Thompson, J. S. Butterworth, Liang Yang, C. R. Brome, G. R. Palmquist, G. L. Yang, Daniel McKinsey, P.-N. Seo, C. E. H. Mattoni, John M. Doyle, C. M. O’Shaughnessy, S. N. Dzhosyuk, Steve K. Lamoreaux, P. R. Huffman, R. A. Michniak, Hans P. Mumm, Robert Golub, Kevin J. Coakley, and E. Korobkina
- Subjects
Condensed Matter::Quantum Gases ,Superconductivity ,Materials science ,Condensed matter physics ,Solenoid ,Superconducting magnet ,Trap (computing) ,Magnet ,Quadrupole ,Physics::Accelerator Physics ,Physics::Atomic Physics ,Current (fluid) ,Quadrupole magnet ,Instrumentation - Abstract
We describe the design, construction, and performance of three generations of superconducting Ioffe magnetic traps. The first two are low current traps, built from four racetrack shaped quadrupole coils and two solenoid assemblies. Coils are wet wound with multifilament NbTi superconducting wires embedded in epoxy matrices. The magnet bore diameters are 51 and 105 mm with identical trap depths of 1.0 T at their operating currents and at 4.2 K. A third trap uses a high current accelerator-type quadrupole magnet and two low current solenoids. This trap has a bore diameter of 140 mm and tested trap depth of 2.8 T. Both low current traps show signs of excessive training. The high current hybrid trap, on the other hand, exhibits good training behavior and is amenable to quench protection.
- Published
- 2008
- Full Text
- View/download PDF
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