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1. A diffuse scattering model of ultracold neutrons on wavy surfaces

Author

Imajo, S., Akatsuka, H., Hatanaka, K., Higuchi, T., Ichikawa, G., Kawasaki, S., Kitaguchi, M., Mammei, R., Matsumiya, R., Mishima, K., Picker, R., Schreyer, W., and Shimizu, H. M.

Subjects
Physics - Instrumentation and Detectors, Nuclear Experiment
Abstract

Metal tubes plated with nickel-phosphorus are used in many fundamental physics experiments using ultracold neutrons (UCN) because of their ease of fabrication. These tubes are usually polished to a average roughness of 25-150 nm. However, there is no scattering model that accurately describes UCN scattering on such a rough guide surface with a mean-square roughness larger than 5 nm. We therefore developed a scattering model for UCN in which scattering from random surface waviness with a size larger than the UCN wavelength is described by a microfacet Bidirectional Reflectance Distribution Function model (mf-BRDF model), and scattering from smaller structures by the Lambert's cosine law (Lambert model). For the surface waviness, we used the statistical distribution of surface slope measured by an atomic force microscope on a sample piece of guide tube as input of the model. This model was used to describe UCN transmission experiments conducted at the pulsed UCN source at J-PARC. In these experiments, a UCN beam collimated to a divergence angle smaller than $\pm 6^{\circ}$ was directed into a guide tube with a mean-square roughness of 6.4 nm to 17 nm at an oblique angle, and the UCN transport performance and its time-of-flight distribution were measured while changing the angle of incidence. The mf-BRDF model combined with the Lambert model with scattering probability $p_{L} = 0.039\pm0.003$ reproduced the experimental results well. We have thus established a procedure to evaluate the characteristics of UCN guide tubes with a surface roughness of approximately 10 nm., Comment: 15 pages, 11 figures. Accepted for publication in PRC

Published
2023
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2. Characterization of electroless nickel-phosphorus plating for ultracold-neutron storage

Author

Akatsuka, H., Andalib, T., Bell, B., Berean-Dutcher, J., Bernier, N., Bidinosti, C. P., Cude-Woods, C., Currie, S. A., Davis, C. A., Franke, B., Gaur, R., Giampa, P., Hansen-Romu, S., Hassan, M. T., Hatanaka, K., Higuchi, T., Gibson, C., Ichikawa, G., Ide, I., Imajo, S., Ito, T. M., Jamieson, B., Kawasaki, S., Kitaguchi, M., Klassen, W., Korkmaz, E., Kuchler, F., Lang, M., Lavvaf, M., Lindner, T., Makela, M., Mammei, J., Mammei, R., Martin, J. W., Matsumiya, R., Miller, E., Mishima, K., Momose, T., Morawetz, S., Morris, C. L., Ong, H. J., O'Shaughnessy, C. M., Pereira-Wilson, M., Picker, R., Piermaier, F., Pierre, E., Schreyer, W., Sidhu, S., Stang, D., Tiepo, V., Vanbergen, S., Wang, R., Wong, D., and Yamamoto, N.

Subjects
Nuclear Experiment
Abstract

Electroless nickel plating is an established industrial process that provides a robust and relatively low-cost coating suitable for transporting and storing ultracold neutrons (UCN). Using roughness measurements and UCN-storage experiments we characterized UCN guides made from polished aluminum or stainless-steel tubes plated by several vendors. All electroless nickel platings were similarly suited for UCN storage with an average loss probability per wall bounce of $2.8\cdot10^{-4}$ to $4.1\cdot10^{-4}$ for energies between 90 neV and 190 neV, or a ratio of imaginary to real Fermi potential $\eta$ of $1.7\cdot10^{-4}$ to $3.3\cdot10^{-4}$. Measurements at different elevations indicate that the energy dependence of UCN losses is well described by the imaginary Fermi potential. Some special considerations are required to avoid an increase in surface roughness during the plating process and hence a reduction in UCN transmission. Increased roughness had only a minor impact on storage properties. Based on these findings we chose a vendor to plate the UCN-production vessel that will contain the superfluid-helium converter for the new TRIUMF UltraCold Advanced Neutron (TUCAN) source, achieving acceptable UCN-storage properties with ${\eta=3.5(5)\cdot10^{-4}}$., Comment: 8 pages, 7 figures

Published
2022
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3. Optimizing neutron moderators for a spallation-driven ultracold-neutron source at TRIUMF

Author

Schreyer, W., Davis, C. A., Kawasaki, S., Kikawa, T., Marshall, C., Mishima, K., Okamura, T., and Picker, R.

Subjects
Physics - Instrumentation and Detectors, Nuclear Experiment, Physics - Accelerator Physics
Abstract

We report on our efforts to optimize the geometry of neutron moderators and converters for the TRIUMF UltraCold Advanced Neutron (TUCAN) source using MCNP simulations. It will use an existing spallation neutron source driven by a 19.3 kW proton beam delivered by TRIUMF's 520 MeV cyclotron. Spallation neutrons will be moderated in heavy water at room temperature and in liquid deuterium at 20 K, and then superthermally converted to ultracold neutrons in superfluid, isotopically purified $^4$He. The helium will be cooled by a $^3$He fridge through a $^3$He-$^4$He heat exchanger. The optimization took into account a range of engineering and safety requirements and guided the detailed design of the source. The predicted ultracold-neutron density delivered to a typical experiment is maximized for a production volume of 27 L, achieving a production rate of $1.4 \cdot 10^7$ s$^{-1}$ to $1.6 \cdot 10^7$ s$^{-1}$ with a heat load of 8.1 W. At that heat load, the fridge can cool the superfluid helium to 1.1 K, resulting in a storage lifetime for ultracold neutrons in the source of about 30 s. The most critical performance parameters are the choice of cold moderator and the volume, thickness, and material of the vessel containing the superfluid helium. The source is scheduled to be installed in 2021 and will enable the TUCAN collaboration to measure the electric dipole moment of the neutron with a sensitivity of $10^{-27}$ e cm.

Published
2019
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4. Improved limits on Fierz Interference using asymmetry measurements from the UCNA experiment

Author

Sun, Xuan, Adamek, E., Allgeier, B., Bagdasarova, Y., Berguno, D. B., Blatnik, M., Bowles, T. J., Broussard, L. J., Brown, M. A. -P., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Dees, E. B., Ding, X., Filippone, B. W., García, A., Geltenbort, P., Hasan, S., Hickerson, K. P., Hoagland, J., Hong, R., Holley, A. T., Ito, T. M., Knecht, A., Liu, C. -Y., Liu, J., Makela, M., Mammei, R., Martin, J. W., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Nepal, S., Nouri, N., Pattie Jr., R. W., Galván, A. Pérez, Phillips II, D. G., Picker, R., Pitt, M. L., Plaster, B., Salvat, D. J., Saunders, A., Sharapov, E. I., Sjue, S., Slutsky, S., Sondheim, W., Swank, C., Tatar, E., Vogelaar, R. B., VornDick, B., Wang, Z., Wei, W., Wexler, J. W., Womack, T., Wrede, C., Young, A. R., and Zeck, B. A.

Subjects
Nuclear Experiment
Abstract

The Ultracold Neutron Asymmetry (UCNA) experiment was designed to measure the $\beta$-decay asymmetry parameter, $A_0$, for free neutron decay. In the experiment, polarized ultracold neutrons are transported into a decay trap, and their $\beta$-decay electrons are detected with $\approx 4\pi$ acceptance into two detector packages which provide position and energy reconstruction. The experiment also has sensitivity to $b_{n}$, the Fierz interference term in the neutron $\beta$-decay rate. In this work, we determine $b_{n}$ from the energy dependence of $A_0$ using the data taken during the UCNA 2011-2013 run. In addition, we present the same type of analysis using the earlier 2010 $A$ dataset. Motivated by improved statistics and comparable systematic errors compared to the 2010 data-taking run, we present a new $b_{n}$ measurement using the weighted average of our asymmetry dataset fits, to obtain $b_{n} = 0.066 \pm 0.041_{\text{stat}} \pm 0.024_{\text{syst}}$ which corresponds to a limit of $-0.012 < b_{n} < 0.144$ at the 90% confidence level., Comment: 6 pages, 3 figures. Submission to PRC

Published
2019
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5. A fast-switching magnet serving a spallation-driven ultracold neutron source

Author

Ahmed, S., Altiere, E., Andalib, T., Barnes, M. J., Bell, B., Bidinosti, C. P., Bylinsky, Y., Chak, J., Das, M., Davis, C. A., Fischer, F., Franke, B., Gericke, M. T. W., Giampa, P., Hahn, M., Hansen-Romu, S., Hatanaka, K., Hayamizu, T., Jamieson, B., Jones, D., Katsika, K., Kawasaki, S., Kikawa, T., Klassen, W., Konaka, A., Korkmaz, E., Kuchler, F., Kurchaninov, L., Lang, M., Lee, L., Lindner, T., Madison, K. W., Mammei, J., Mammei, R., Martin, J. W., Matsumiya, R., Miller, E., Momose, T., Picker, R., Pierre, E., Ramsay, W. D., Rao, Y. -N., Rawnsley, W. R., Rebenitsch, L., Schreyer, W., Sidhu, S., Vanbergen, S., van Oers, W. T. H., Watanabe, Y. X., and Yosifov, D.

Subjects
Physics - Accelerator Physics, Nuclear Experiment, Physics - Instrumentation and Detectors
Abstract

A fast-switching, high-repetition-rate magnet and power supply have been developed for and operated at TRIUMF, to deliver a proton beam to the new ultracold neutron (UCN) facility. The facility possesses unique operational requirements: a time-averaged beam current of 40~$\mu$A with the ability to switch the beam on or off for several minutes. These requirements are in conflict with the typical operation mode of the TRIUMF cyclotron which delivers nearly continuous beam to multiple users. To enable the creation of the UCN facility, a beam-sharing arrangement with another facility was made. The beam sharing is accomplished by the fast-switching (kicker) magnet which is ramped in 50~$\mu$s to a current of 193~A, held there for approximately 1~ms, then ramped down in the same short period of time. This achieves a 12~mrad deflection which is sufficient to switch the proton beam between the two facilities. The kicker magnet relies on a high-current, low-inductance coil connected to a fast-switching power supply that is based on insulated-gate bipolar transistors (IGBTs). The design and performance of the kicker magnet system and initial beam delivery results are reported., Comment: 16 pages, 21 figures

Published
2019
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6. Final results for the neutron $\beta$-asymmetry parameter $A_0$ from the UCNA experiment

Author

Plaster, B., Adamek, E., Allgeier, B., Anaya, J., Back, H. O., Bagdasarova, Y., Berguno, D. B., Blatnik, M., Boissevain, J. G., Bowles, T. J., Broussard, L. J., Brown, M. A. -P., Carr, R., Clark, D. J., Clayton, S., Cude-Woods, C., Currie, S., Dees, E. B., Ding, X., Du, S., Filippone, B. W., Garcia, A., Geltenbort, P., Hasan, S., Hawari, A., Hickerson, K. P., Hill, R., Hino, M., Hoagland, J., Hoedl, S. A., Hogan, G. E., Hona, B., Hong, R., Holley, A. T., Ito, T. M., Kawai, T., Kirch, K., Kitagaki, S., Knecht, A., Lamoreaux, S. K., Liu, C. -Y., Liu, J., Makela, M., Mammei, R. R., Martin, J. W., Meier, N., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Mortensen, R., Nepal, S., Nouri, N., Pattie, R. W., Galvan, A. Perez, Phillips, D. G., Pichlmaier, A., Picker, R., Pitt, M. L., Ramsey, J. C., Rios, R., Russell, R., Sabourov, K., Sallaska, A. L., Salvat, D. J., Saunders, A., Schmid, R., Seestrom, S. J., Servicky, C., Sharapov, E. I., Sjue, S. K. L., Slutsky, S., Smith, D., Sondheim, W. E., Sun, X., Swank, C., Swift, G., Tatar, E., Teasdale, W., Terai, C., Tipton, B., Utsuro, M., Vogelaar, R. B., VornDick, B., Wang, Z., Wehring, B., Wexler, J., Womack, T., Wrede, C., Xu, Y. P., Yan, H., Young, A. R., Yuan, J., and Zeck, B. A.

Subjects
Nuclear Experiment, Physics - Instrumentation and Detectors
Abstract

The UCNA experiment was designed to measure the neutron $\beta$-asymmetry parameter $A_0$ using polarized ultracold neutrons (UCN). UCN produced via downscattering in solid deuterium were polarized via transport through a 7 T magnetic field, and then directed to a 1 T solenoidal electron spectrometer, where the decay electrons were detected in electron detector packages located on the two ends of the spectrometer. A value for $A_0$ was then extracted from the asymmetry in the numbers of counts in the two detector packages. We summarize all of the results from the UCNA experiment, obtained during run periods in 2007, 2008--2009, 2010, and 2011--2013, which ultimately culminated in a 0.67\% precision result for $A_0$., Comment: 6 pages, 7 figures, to appear in proceedings of the International Workshop on Particle Physics at Neutron Sources 2018

Published
2019
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7. Characterization of electroless nickel-phosphorus plating for ultracold-neutron storage

Author

Akatsuka, H., Andalib, T., Bell, B., Berean-Dutcher, J., Bernier, N., Bidinosti, C.P., Cude-Woods, C., Currie, S.A., Davis, C.A., Franke, B., Gaur, R., Giampa, P., Hansen-Romu, S., Hassan, M.T., Hatanaka, K., Higuchi, T., Gibson, C., Ichikawa, G., Ide, I., Imajo, S., Ito, T.M., Jamieson, B., Kawasaki, S., Kitaguchi, M., Klassen, W., Korkmaz, E., Kuchler, F., Lang, M., Lavvaf, M., Lindner, T., Makela, M., Mammei, J., Mammei, R., Martin, J.W., Matsumiya, R., Miller, E., Mishima, K., Momose, T., Morawetz, S., Morris, C.L., Ong, H.J., O’Shaughnessy, C.M., Pereira-Wilson, M., Picker, R., Piermaier, F., Pierre, E., Schreyer, W., Sidhu, S., Stang, D., Tiepo, V., Vanbergen, S., Wang, R., Wong, D., and Yamamoto, N.

Published
2023
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8. The Nab Experiment: A Precision Measurement of Unpolarized Neutron Beta Decay

Author

Fry, J., Alarcon, R., Baessler, S., Balascuta, S., Barron-Palos, L., Bailey, T., Bass, K., Birge, N., Blose, A., Borissenko, D., Bowman, J. D., Broussard, L. J., Bryant, A. T., Byrne, J., Calarco, J. R., Caylor, J., Chang, K., Chupp, T., Cianciolo, T. V., Crawford, C., Ding, X., Doyle, M., Fan, W., Farrar, W., Fomin, N., Frlez, E., Gericke, M. T., Gervais, M., Gluck, F., Greene, G. L., Grzywacz, R. K., Gudkov, V., Hamblen, J., Hayes, C., Hendrus, C., Ito, T., Jezghani, A., Li, H., Makela, M., Macsai, N., Mammei, J., Mammei, R., Martinez, M., Mathews, D. G., McCrea, M., McGaughey, P., McLaughlin, C. D., Mueller, P., van Petten, D., Penttila, S. I., Perryman, D. E., Picker, R., Pierce, J., Pocanic, D., Qian, Y., Ramsey, J., Randall, G., Riley, G., Rykaczewski, K. P., Salas-Bacci, A., Samiei, S., Scott, E. M., Shelton, T., Sjue, S. K., Smith, A., Smith, E., Stevens, E., Wexler, J., Whitehead, R., Wilburn, W. S., Young, A., and Zeck, B.

Subjects
Nuclear Experiment
Abstract

Neutron beta decay is one of the most fundamental processes in nuclear physics and provides sensitive means to uncover the details of the weak interaction. Neutron beta decay can evaluate the ratio of axial-vector to vector coupling constants in the standard model, $\lambda = g_A / g_V$, through multiple decay correlations. The Nab experiment will carry out measurements of the electron-neutrino correlation parameter $a$ with a precision of $\delta a / a = 10^{-3}$ and the Fierz interference term $b$ to $\delta b = 3\times10^{-3}$ in unpolarized free neutron beta decay. These results, along with a more precise measurement of the neutron lifetime, aim to deliver an independent determination of the ratio $\lambda$ with a precision of $\delta \lambda / \lambda = 0.03\%$ that will allow an evaluation of $V_{ud}$ and sensitively test CKM unitarity, independent of nuclear models. Nab utilizes a novel, long asymmetric spectrometer that guides the decay electron and proton to two large area silicon detectors in order to precisely determine the electron energy and an estimation of the proton momentum from the proton time of flight. The Nab spectrometer is being commissioned at the Fundamental Neutron Physics Beamline at the Spallation Neutron Source at Oak Ridge National Lab. We present an overview of the Nab experiment and recent updates on the spectrometer, analysis, and systematic effects., Comment: Presented at PPNS2018

Published
2018
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9. A beamline for fundamental neutron physics at TRIUMF

Author

Ahmed, S., Andalib, T., Barnes, M. J., Bidinosti, C. B., Bylinsky, Y., Chak, J., Das, M., Davis, C. A., Franke, B., Gericke, M. T. W., Giampa, P., Hahn, M., Hansen-Romu, S., Hatanaka, K., Jamieson, B., Jones, D., Katsika, K., Kawasaki, S., Klassen, W., Konaka, A., Korkmaz, E., Kuchler, F., Kurchaninov, L., Lang, M., Lee, L., Lindner, T., Madison, K. W., Mammei, J., Mammei, R., Martin, J. W., Matsumiya, R., Picker, R., Pierre, E., Ramsay, W. D., Rao, Y. -N., Rawnsley, W. R., Rebenitsch, L., Remon, C. A., Schreyer, W., Sikora, A., Sidhu, S., Sonier, J., Thorsteinson, B., Vanbergen, S., van Oers, W. T. H., Watanabe, Y. X., and Yosifov, D.

Subjects
Physics - Instrumentation and Detectors
Abstract

This article describes the new primary proton beamline 1U at TRIUMF. The purpose of this beamline is to produce ultracold neutrons (UCN) for fundamental-physics experiments. It delivers up to 40 microA of 480 MeV protons from the TRIUMF cyclotron to a tungsten spallation target and uses a fast kicker to share the beam between the Center for Molecular and Materials Science and UCN. The beamline has been successfully commissioned and operated with a beam current up to 10 microA, facilitating first large-scale UCN production in Canada.

Published
2018
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10. First ultracold neutrons produced at TRIUMF

Author

Ahmed, S., Altiere, E., Andalib, T., Bell, B., Bidinosti, C. P., Cudmore, E., Das, M., Davis, C. A., Franke, B., Gericke, M., Giampa, P., Gnyp, P., Hansen-Romu, S., Hatanaka, K., Hayamizu, T., Jamieson, B., Jones, D., Kawasaki, S., Kikawa, T., Kitaguchi, M., Klassen, W., Konaka, A., Korkmaz, E., Kuchler, F., Lang, M., Lee, L., Lindner, T., Madison, K. W., Makida, Y., Mammei, J., Mammei, R., Martin, J. W., Matsumiya, R., Miller, E., Mishima, K., Momose, T., Okamura, T., Page, S., Picker, R., Pierre, E., Ramsay, W. D., Rebenitsch, L., Rehm, F., Schreyer, W., Shimizu, H. M., Sidhu, S., Sikora, A., Smith, J., Tanihata, I., Thorsteinson, B., Vanbergen, S., van Oers, W. T. H., and Watanabe, Y. X.

Subjects
Physics - Instrumentation and Detectors, Nuclear Experiment
Abstract

We installed a source for ultracold neutrons at a new, dedicated spallation target at TRIUMF. The source was originally developed in Japan and uses a superfluid-helium converter cooled to 0.9$\,$K. During an extensive test campaign in November 2017, we extracted up to 325000 ultracold neutrons after a one-minute irradiation of the target, over three times more than previously achieved with this source. The corresponding ultracold-neutron density in the whole production and guide volume is 5.3$\,$cm$^{-3}$. The storage lifetime of ultracold neutrons in the source was initially 37$\,$s and dropped to 24$\,$s during the eighteen days of operation. During continuous irradiation of the spallation target, we were able to detect a sustained ultracold-neutron rate of up to 1500$\,$s$^{-1}$. Simulations of UCN production, UCN transport, temperature-dependent UCN yield, and temperature-dependent storage lifetime show excellent agreement with the experimental data and confirm that the ultracold-neutron-upscattering rate in superfluid helium is proportional to $T^7$., Comment: 8 pages, 10 figures

Published
2018
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11. Monte Carlo simulations for the optimization and data analysis of experiments with ultracold neutrons

Author

Ayres, N. J., Chanel, E., Clement, B., Harris, P. G., Picker, R., Pignol, G., Schreyer, W., and Zsigmond, G.

Subjects
Physics - Instrumentation and Detectors, Physics - Computational Physics, Physics - Data Analysis, Statistics and Probability
Abstract

Ultracold neutrons (UCN) with kinetic energies up to 300 neV can be stored in material or magnetic confinements for hundreds of seconds. This makes them a very useful tool for probing fundamental symmetries of nature, by searching for charge-parity violation by a neutron electric dipole moment, and yielding important parameters for Big Bang nucleosynthesis, e.g. in neutron-lifetime measurements. Further increasing the intensity of UCN sources is crucial for next-generation experiments. Advanced Monte Carlo (MC) simulation codes are important in optimization of neutron optics of UCN sources and of experiments, but also in estimation of systematic effects, and in bench-marking of analysis codes. Here we will give a short overview of recent MC simulation activities in this field., Comment: NOP2017 conference proceedings paper accepted in JPS Conference Proceedings

Published
2018
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12. Search for dark matter decay of the free neutron from the UCNA experiment: n $\rightarrow \chi + e^+e^-$

Author

Sun, X., Adamek, E., Allgeier, B., Blatnik, M., Bowles, T. J., Broussard, L. J., Brown, M. A. -P., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Dees, E. B., Ding, X., Filippone, B. W., García, A., Geltenbort, P., Hasan, S., Hickerson, K. P., Hoagland, J., Hong, R., Hogan, G. E., Holley, A. T., Ito, T. M., Knecht, A., Liu, C. -Y., Liu, J., Makela, M., Mammei, R., Martin, J. W., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Nepal, S., Nouri, N., Pattie, Jr., R. W., Galván, A. Pérez, Phillips II, D. G., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Salvat, D. J., Saunders, A., Sondheim, W., Sjue, S., Slutsky, S., Swank, C., Swift, G., Tatar, E., Vogelaar, R. B., VornDick, B., Wang, Z., Wei, W., Wexler, J., Womack, T., Wrede, C., Young, A. R., and Zeck, B. A.

Subjects
Nuclear Experiment, Physics - Instrumentation and Detectors
Abstract

It has been proposed recently that a previously unobserved neutron decay branch to a dark matter particle ($\chi$) could account for the discrepancy in the neutron lifetime observed in experiments that use two different measurement techniques. One of the possible final states discussed includes a single $\chi$ along with an $e^{+}e^{-}$ pair. We use data from the UCNA (Ultracold Neutron Asymmetry) experiment to set limits on this decay channel. Coincident electron-like events are detected with $\sim 4\pi$ acceptance using a pair of detectors that observe a volume of stored Ultracold Neutrons (UCNs). The summed kinetic energy ($E_{e^{+}e^{-}}$) from such events is used to set limits, as a function of the $\chi$ mass, on the branching fraction for this decay channel. For $\chi$ masses consistent with resolving the neutron lifetime discrepancy, we exclude this as the dominant dark matter decay channel at $\gg~5\sigma$ level for $100~\text{keV} < E_{e^{+}e^{-}} < 644~\text{keV}$. If the $\chi+e^{+}e^{-}$ final state is not the only one, we set limits on its branching fraction of $< 10^{-4}$ for the above $E_{e^{+}e^{-}}$ range at $> 90\%$ confidence level., Comment: 5 pages, 5 figures

Published
2018
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13. New result for the neutron $\beta$-asymmetry parameter $A_0$ from UCNA

Author

Brown, M. A. -P., Dees, E. B., Adamek, E., Allgeier, B., Blatnik, M., Bowles, T. J., Broussard, L. J., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Ding, X., Filippone, B. W., Garcia, A., Geltenbort, P., Hasan, S., Hickerson, K. P., Hoagland, J., Hong, R., Hogan, G. E., Holley, A. T., Ito, T. M., Knecht, A., Liu, C. -Y., Liu, J., Makela, M., Martin, J. W., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Nepal, S., Nouri, N., Pattie, Jr., R. W., Perez-Galvan, A., Phillips II, D. G., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Salvat, D. J., Saunders, A., Sondheim, W., Seestrom, S. J., Sjue, S., Slutsky, S., Sun, X., Swank, C., Swift, G., Tatar, E., Vogelaar, R. B., VornDick, B., Wang, Z., Wexler, J., Womack, T., Wrede, C., Young, A. R., and Zeck, B. A.

Subjects
Nuclear Experiment
Abstract

The neutron $\beta$-decay asymmetry parameter $A_0$ defines the correlation between the spin of the neutron and the momentum of the emitted electron, which determines $\lambda=\frac{g_{A}}{g_{V}}$, the ratio of the axial-vector to vector weak coupling constants. The UCNA Experiment, located at the Ultracold Neutron facility at the Los Alamos Neutron Science Center, is the first to measure such a correlation coefficient using ultracold neutrons (UCN). Following improvements to the systematic uncertainties and increased statistics, we report the new result $A_0 = -0.12054(44)_{\mathrm{stat}}(68)_{\mathrm{syst}}$ which yields $\lambda\equiv \frac{g_{A}}{g_{V}}=-1.2783(22)$. Combination with the previous UCNA result and accounting for correlated systematic uncertainties produces $A_0=-0.12015(34)_{\mathrm{stat}}(63)_{\mathrm{syst}}$ and $\lambda\equiv \frac{g_{A}}{g_{V}}=-1.2772(20)$., Comment: 9 pages, 7 figures, updated to as-published version

Published
2017
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14. First direct constraints on Fierz interference in free neutron $\beta$ decay

Author

Hickerson, K. P., Sun, X., Bagdasarova, Y., Bravo-Berguño, D., Broussard, L. J., Brown, M. A. -P., Carr, R., Currie, S., Ding, X., Filippone, B. W., García, A., Geltenbort, P., Hoagland, J., Holley, A. T., Hong, R., Ito, T. M., Knecht, A., Liu, C. -Y., Liu, J. L., Makela, M., Mammei, R. R., Martin, J. W., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Pattie, Jr., R. W., Galván, A. Pérez, Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Saunders, A., Seestrom, S. J., Sharapov, E. I., Sondheim, W. E., Tatar, E., Vogelaar, R. B., VornDick, B., Wrede, C., Young, A. R., and Zeck, B. A.

Subjects
Nuclear Experiment
Abstract

Precision measurements of free neutron $\beta$-decay have been used to precisely constrain our understanding of the weak interaction. However the neutron Fierz interference term $b_n$, which is particularly sensitive to Beyond-Standard-Model tensor currents at the TeV scale, has thus far eluded measurement. Here we report the first direct constraints on this term, finding $b_n = 0.067 \pm 0.005_{\text{stat}} {}^{+0.090}_{- 0.061}{}_{\text{sys}}$, consistent with the Standard Model. The uncertainty is dominated by absolute energy reconstruction and the linearity of the beta spectrometer energy response.

Published
2017
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15. Cryogenic magnetic coil and superconducting magnetic shield for neutron electric dipole moment searches

Author

Slutsky, S., Swank, C. M., Biswas, A., Carr, R., Escribano, J., Filippone, B. W., Griffith, W. C., Mendenhall, M., Nouri, N., Osthelder, C., Galván, A. Pérez, Picker, R., and Plaster, B.

Subjects
Physics - Instrumentation and Detectors, Nuclear Experiment
Abstract

A magnetic coil operated at cryogenic temperatures is used to produce spatial, relative field gradients below 6 ppm/cm, stable for several hours. The apparatus is a prototype of the magnetic components for a neutron electric dipole moment (nEDM) search, which will take place at the Spallation Neutron Source (SNS) at Oak Ridge National Laboratory using ultra-cold neutrons (UCN). That search requires a uniform magnetic field to mitigate systematic effects and obtain long polarization lifetimes for neutron spin precession measurements. This paper details upgrades to a previously described apparatus, particularly the introduction of super-conducting magnetic shielding and the associated cryogenic apparatus. The magnetic gradients observed are sufficiently low for the nEDM search at SNS., Comment: 26 pages, 19 figures; significant updates in response to referee comments. Reworked Section 3.2 for clarity. Added several Figures for clarity, and indicated orientation better in many Figures. Fixed typographical problems. Updated an author's attribution to reflect current place of work. Updated conclusions to better indicate future steps needed

Published
2017
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17. Precision Measurement of the Neutron Beta-Decay Asymmetry

Author

Mendenhall, M. P., Pattie Jr, R. W., Bagdasarova, Y., Berguno, D. B., Broussard, L. J., Carr, R., Currie, S., Ding, X., Filippone, B. W., García, A., Geltenbort, P., Hickerson, K. P., Hoagland, J., Holley, A. T., Hong, R., Ito, T. M., Knecht, A., Liu, C. -Y., Liu, J. L., Makela, M., Mammei, R. R., Martin, J. W., Melconian, D., Moore, S. D., Morris, C. L., Galván, A. Pérez, Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Saunders, A., Seestrom, S. J., Sharapov, E. I., Sondheim, W. E., Tatar, E., Vogelaar, R. B., VornDick, B., Wrede, C., Young, A. R., and Zeck, B. A.

Subjects
Nuclear Experiment
Abstract

A new measurement of the neutron $\beta$-decay asymmetry $A_0$ has been carried out by the UCNA collaboration using polarized ultracold neutrons (UCN) from the solid deuterium UCN source at the Los Alamos Neutron Science Center (LANSCE). Improvements in the experiment have led to reductions in both statistical and systematic uncertainties leading to $A_0 = -0.11954(55)_{\rm stat.}(98)_{\rm syst.}$, corresponding to the ratio of axial-vector to vector coupling $\lambda \equiv g_A/g_V = -1.2756(30)$.

Published
2012
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18. Diffuse scattering model of ultracold neutrons on wavy surfaces

Author

Imajo, S., primary, Akatsuka, H., additional, Hatanaka, K., additional, Higuchi, T., additional, Ichikawa, G., additional, Kawasaki, S., additional, Kitaguchi, M., additional, Mammei, R., additional, Matsumiya, R., additional, Mishima, K., additional, Picker, R., additional, Schreyer, W., additional, and Shimizu, H. M., additional

Published
2023
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20. The Nab experiment: A precision measurement of unpolarized neutron beta decay

Author

Fry J., Alarcon R., Baeßler S., Balascuta S., Palos L. Barrón, Bailey T., Bass K., Birge N., Blose A., Borissenko D., Bowman J.D., Broussard L.J., Bryant A.T., Byrne J., Calarco J.R., Caylor J., Chang K., Chupp T., Cianciolo T.V., Crawford C., Ding X., Doyle M., Fan W., Farrar W., Fomin N., Frlež E., Gericke M.T., Gervais M., Glück F., Greene G.L., Grzywacz R.K., Gudkov V., Hamblen J., Hayes C., Hendrus C., Ito T., Jezghani A., Li H., Makela M., Macsai N., Mammei J., Mammei R., Martinez M., Matthews D.G., McCrea M., McGaughey P., McLaughlin C.D., Mueller P., Petten D. van, Penttilä S.I., Perryman D.E., Picker R., Pierce J., Počanić D., Qian Y., Ramsey J., Randall G., Riley G., Rykaczewski K.P., Salas-Bacci A., Samiei S., Scott E.M., Shelton T., Sjue S.K., Smith A., Smith E., Stevens E., Wexler J., Whitehead R., Wilburn W.S., Young A., and Zeck B.

Subjects
Physics, QC1-999
Abstract

Neutron beta decay is one of the most fundamental processes in nuclear physics and provides sensitive means to uncover the details of the weak interaction. Neutron beta decay can evaluate the ratio of axial-vector to vector coupling constants in the standard model, λ = gA/gV, through multiple decay correlations. The Nab experiment will carry out measurements of the electron-neutrino correlation parameter a with a precision of δa/a = 10−3 and the Fierz interference term b to δb = 3 × 10−3 in unpolarized free neutron beta decay. These results, along with a more precise measurement of the neutron lifetime, aim to deliver an independent determination of the ratio λ with a precision of δλ/λ = 0.03% that will allow an evaluation of Vud and sensitively test CKM unitarity, independent of nuclear models. Nab utilizes a novel, long asymmetric spectrometer that guides the decay electron and proton to two large area silicon detectors in order to precisely determine the electron energy and an estimation of the proton momentum from the proton time of flight. The Nab spectrometer is being commissioned at the Fundamental Neutron Physics Beamline at the Spallation Neutron Source at Oak Ridge National Lab. We present an overview of the Nab experiment and recent updates on the spectrometer, analysis, and systematic effects.

Published
2019
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21. Search for neutron dark decay: n → χ + e+e−

Author

Sun X., Adamek E., Allgeier B., Blatnik M., Bowles T.J., Broussard L.J., Brown M.A.-P., Carr R., Clayton S., Cude-Woods C., Currie S., Dees E.B., Ding X., Filippone B.W., García A., Geltenbort P., Hasan S., Hickerson K.P., Hoagland J., Hong R., Hogan G.E., Holley A.T., Ito T.M., Kneckt A., Liu C.-Y., Liu J., Makela M., Mammei R., Martin J.W., Melconian D., Mendenhall M.P., Moore S.D., Morris C.L., Nepal S., Nouri N., Pattie R.W., Galván A.P., Phillips II D.G., Picker R., Pitt M.L., Plaster B., Ramsey J.C., Rios R., Salvat D.J., Saunders A., Sondheim W., Sjue S., Slutsky S., Swank C., Swift G., Tatar E., Vogelaar R.B., VornDick B., Wanchun W., Wang Z., Wexler J., Womack T., Wrede C., Young A.R., and Zeck B.A.

Subjects
Physics, QC1-999
Abstract

In January, 2018, Fornal and Grinstein proposed that a previously unobserved neutron decay branch to a dark matter particle (χ) could account for the discrepancy in the neutron lifetime observed in two different types of experiments. One of the possible final states discussed includes a single χ along with an e+e− pair. We use data from the UCNA (Ultracold Neutron Asymmetry) experiment to set limits on this decay channel. Coincident electron-like events are detected with ∼ 4π acceptance using a pair of detectors that observe a volume of stored Ultracold Neutrons (UCNs). We use the timing information of coincidence events to select candidate dark sector particle decays by applying a timing calibration and selecting events within a physically-forbidden timing region for conventional n → p + e- + ν̅e decays. The summed kinetic energy (Ee+e−) from such events is reconstructed and used to set limits, as a function of the χ mass, on the branching fraction for this decay channel.

Published
2019
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27. Final results for the neutron β-asymmetry parameter A₀ from the UCNA experiment

Author

Plaster, B., Adamek, E., Allgeier, B., Anaya, J., Back, H. O., Bagdasarova, Y., Berguno, D. B., Blatnik, M., Boissevain, J. G., Bowles, T. J., Broussard, L. J., Brown, M. A.-P., Carr, R., Clark, D. J., Clayton, S., Cude-Woods, C., Currie, S., Dees, E. B., Ding, X., Du, S., Filippone, B. W., García, A., Geltenbort, P., Hasan, S., Hawari, A., Hickerson, K. P., Hill, R., Hino, M., Hoagland, J., Hoedl, S. A., Hogan, G. E., Hona, B., Hong, R., Holley, A. T., Ito, T. M., Kawai, T., Kirch, K., Kitagaki, S., Knecht, A., Lamoreaux, S. K., Liu, C.-Y., Liu, J., Makela, M., Mammei, R. R., Martin, J. W., Meier, N., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Mortensen, R., Nepal, S., Nouri, N., Pattie, R. W., Pérez Galván, A., Phillips II, D. G., Pichlmaier, A., Picker, R., Pitt, M. L., Ramsey, J. C., Rios, R., Russell, R., Sabourov, K., Sallaska, A. L., Salvat, D. J., Saunders, A., Schmid, R., Seestrom, S. J., Servicky, C., Sharapov, E. I., Sjue, S. K. L., Slutsky, S., Smith, D., Sondheim, W. E., Sun, X., Swank, C., Swift, G., Tatar, E., Teasdale, W., Terai, C., Tipton, B., Utsuro, M., Vogelaar, R. B., VornDick, B., Wang, Z., Wehring, B., Wexler, J., Womack, T., Wrede, C., Xu, Y. P., Yan, H., Young, A. R., Yuan, J., and Zeck, B. A.

Subjects
Physics::Instrumentation and Detectors, High Energy Physics::Experiment, Nuclear Experiment
Abstract

The UCNA experiment was designed to measure the neutron β-asymmetry parameter A0 using polarized ultracold neutrons (UCN). UCN produced via downscattering in solid deuterium were polarized via transport through a 7 T magnetic field, and then directed to a 1 T solenoidal electron spectrometer, where the decay electrons were detected in electron detector packages located on the two ends of the spectrometer. A value for A0 was then extracted from the asymmetry in the numbers of counts in the two detector packages. We summarize all of the results from the UCNA experiment, obtained during run periods in 2007, 2008–2009, 2010, and 2011–2013, which ultimately culminated in a 0.67% precision result for A₀.

Published
2019

29. A superconducting magnet UCN trap for precise neutron lifetime measurements

Author

Picker, R., Altarev, I., Brocker, J., Gutsmiedl, E., Hartmann, J., Muller, A., Paul, S., Schott, W., Trinks, U., and Zimmer, O.

Subjects
Magnetic traps -- Thermal properties -- Atomic properties -- Research -- Analysis, Beta decay -- Research -- Thermal properties -- Analysis, Monte Carlo method -- Analysis -- Thermal properties -- Research
Abstract

Finite-element methods along with Monte Carlo simulations were used to design a magnetic storage device for ultracold neutrons (UCN) to measure their lifetime. A setup was determined which should make […]

Published
2005

30. First ever storage of ultracold neutrons in a magnetic trap made of permanent magnets

Author

Ezhov, V.F., Andreev, A.Z., Glushkov, A.A., Glushkov, A.G., Groshev, M.N., Knyazkov, V.A., Krygin, G.B., Ryabov, V.L., Serebrov, A.P., Bazarov, B.A., Geltenbort, P., Hartman, F.J., Paul, S., Picker, R., Zimmer, O., and Kovrizhnykh, N.A.

Subjects
Magnetic traps -- Thermal properties -- Atomic properties -- Research, Beta decay -- Research -- Thermal properties
Abstract

Further improvement in the accuracy of any neutron lifetime experiment by means of ultracold neutrons (UCN) in material bottles is limited due to unavoidable systematic effects when the UCN are […]

Published
2005

31. Improved limits on Fierz Interference using asymmetry measurements from the UCNA experiment

Author

Sun, X., Adamek, E., Allgeier, B., Bagdasarova, Y., Berguno, D.B., Blatnik, M., Bowles, T.J., Broussard, L.J., Brown, M.A.-P., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Dees, E.B., Ding, X., Filippone, B.W., GarcÍa, A., Geltenbort, P., Hasan, S., Hickerson, K.P., Hoagland, J., Hong, R., Holley, A.T., Ito, T.M., Knecht, A., Liu, C.-Y., Liu, J., Makela, M., Mammei, R., Martin, J.W., Melconian, D., Mendenhall, M.P., Moore, S.D., Morris, C.L., Nepal, S., Nouri, N., Pattie, R.W., Pérez Galván, A., Phillips, D.G., Picker, R., Pitt, M.L., Plaster, B., Salvat, D.J., Saunders, A., Sharapov, E.I., Sjue, S., Slutsky, S., Sondheim, W., Swank, C., Tatar, E., Vogelaar, R.B., Vorndick, B., Wang, Z., Wei, W., Wexler, J.W., Womack, T., Wrede, C., Young, A.R., Zeck, B.A., Institut Laue-Langevin (ILL), ILL, and UCNA

Subjects
FOS: Physical sciences, High Energy Physics::Experiment, Nuclear Experiment (nucl-ex), [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Nuclear Experiment
Abstract

The Ultracold Neutron Asymmetry (UCNA) experiment was designed to measure the $\beta$-decay asymmetry parameter, $A_0$, for free neutron decay. In the experiment, polarized ultracold neutrons are transported into a decay trap, and their $\beta$-decay electrons are detected with $\approx 4\pi$ acceptance into two detector packages which provide position and energy reconstruction. The experiment also has sensitivity to $b_{n}$, the Fierz interference term in the neutron $\beta$-decay rate. In this work, we determine $b_{n}$ from the energy dependence of $A_0$ using the data taken during the UCNA 2011-2013 run. In addition, we present the same type of analysis using the earlier 2010 $A$ dataset. Motivated by improved statistics and comparable systematic errors compared to the 2010 data-taking run, we present a new $b_{n}$ measurement using the weighted average of our asymmetry dataset fits, to obtain $b_{n} = 0.066 \pm 0.041_{\text{stat}} \pm 0.024_{\text{syst}}$ which corresponds to a limit of $-0.012 < b_{n} < 0.144$ at the 90% confidence level., Comment: 6 pages, 3 figures. Submission to PRC

Published
2019

32. Search for neutron dark decay: n $\rightarrow \chi + e^+e^-$

Author

Sun, X., Adamek, E., Allgeier, B., Blatnik, M., Bowles, T.J., Broussard, L.J., Brown, M.A.P., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Dees, E.B., Ding, X., Filippone, B.W., GarcÍa, A., Geltenbort, P., Hasan, S., Hickerson, K.P., Hoagland, J., Hong, R., Hogan, G.E., Holley, A.T., Ito, T.M., Kneckt, A., Liu, C.Y., Liu, J., Makela, M., Mammei, R., Martin, J.W., Melconian, D., Mendenhall, M.P., Moore, S.D., Morris, C.L., Nepal, S., Nouri, N., Pattie, R.W., Galván, A.P., II, D.G.Phillips, Picker, R., Pitt, M.L., Plaster, B., Ramsey, J.C., Rios, R., Salvat, D.J., Saunders, A., Sondheim, W., Sjue, S., Slutsky, S., Swank, C., Swift, G., Tatar, E., Vogelaar, R.B., Vorndick, B., Wanchun, W., Wang, Z., Wexler, J., Womack, T., Wrede, C., Young, A.R., Zeck, B.A., Institut Laue-Langevin (ILL), and ILL

Subjects
energy: kinetic, branching ratio: upper limit, n: decay, n: branching ratio, talk: Grenoble 2018/05/24, calibration, dark matter, mass dependence, electron: pair production, [PHYS.HEXP]Physics [physics]/High Energy Physics - Experiment [hep-ex], High Energy Physics::Experiment, n: lifetime, acceptance, experimental results
Abstract

International audience; In January, 2018, Fornal and Grinstein proposed that a previously unobserved neutron decay branch to a dark matter particle (χ) could account for the discrepancy in the neutron lifetime observed in two different types of experiments. One of the possible final states discussed includes a single χ along with an e+e− pair. We use data from the UCNA (Ultracold Neutron Asymmetry) experiment to set limits on this decay channel. Coincident electron-like events are detected with ∼ 4π acceptance using a pair of detectors that observe a volume of stored Ultracold Neutrons (UCNs). We use the timing information of coincidence events to select candidate dark sector particle decays by applying a timing calibration and selecting events within a physically-forbidden timing region for conventional n → p + e- + ν̅e decays. The summed kinetic energy (Ee+e−) from such events is reconstructed and used to set limits, as a function of the χ mass, on the branching fraction for this decay channel.

Published
2018

33. New result for the neutron β-asymmetry parameter A_0 from UCNA

Author

Brown, M. A.-P., Blatnik, M., Carr, R., Filippone, B. W., Hickerson, K. P., Martin, J. W., Mendenhall, M. P., Pérez Galván, A., Picker, R., Slutsky, S., Sun, X., and Swank, C.

Subjects
High Energy Physics::Experiment, Nuclear Experiment
Abstract

Background: The neutron β-decay asymmetry parameter A_0 defines the angular correlation between the spin of the neutron and the momentum of the emitted electron. Values for A_0 permit an extraction of the ratio of the weak axial-vector to vector coupling constants, λ≡gA/gV, which under assumption of the conserved vector current hypothesis (gV=1) determines gA. Precise values for gA are important as a benchmark for lattice QCD calculations and as a test of the standard model. Purpose: The UCNA experiment, carried out at the Ultracold Neutron (UCN) source at the Los Alamos Neutron Science Center, was the first measurement of any neutron β-decay angular correlation performed with UCN. This article reports the most precise result for A_0 obtained to date from the UCNA experiment, as a result of higher statistics and reduced key systematic uncertainties, including from the neutron polarization and the characterization of the electron detector response. Methods: UCN produced via the downscattering of moderated spallation neutrons in a solid deuterium crystal were polarized via transport through a 7 T polarizing magnet and a spin flipper, which permitted selection of either spin state. The UCN were then contained within a 3-m long cylindrical decay volume, situated along the central axis of a superconducting 1 T solenoidal spectrometer. With the neutron spins then oriented parallel or anti-parallel to the solenoidal field, an asymmetry in the numbers of emitted decay electrons detected in two electron detector packages located on both ends of the spectrometer permitted an extraction of A_0. Results: The UCNA experiment reports a new 0.67% precision result for A_0 of A_0=−0.12054(44)_(stat)(68)_(syst), which yields λ=gA/gV=−1.2783(22). Combination with the previous UCNA result and accounting for correlated systematic uncertainties produces A0=−0.12015(34)stat(63)syst and λ=gA/gV=−1.2772(20). Conclusions: This new result for A0 and gA/gV from the UCNA experiment has provided confirmation of the shift in values for gA/gV that has emerged in the published results from more recent experiments, which are in striking disagreement with the results from older experiments. Individual systematic corrections to the asymmetries in older experiments (published prior to 2002) were >10%, whereas those in the more recent ones (published after 2002) have been of the scale of

Published
2018

34. New result for the neutron $\beta$-asymmetry parameter $A_0$ from UCNA

Author

Brown, M.A.-P., Dees, E.B., Adamek, E., Allgeier, B., Blatnik, M., Bowles, T.J., Broussard, L.J., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Ding, X., Filippone, B.W., GarcÍa, A., Geltenbort, P., Hasan, S., Hickerson, K.P., Hoagland, J., Hong, R., Hogan, G.E., Holley, A.T., Ito, T.M., Knecht, A., Liu, C.-Y., Liu, J., Makela, M., Martin, J.W., Melconian, D., Mendenhall, M.P., Moore, S.D., Morris, C.L., Nepal, S., Nouri, N., Pattie, R.W., Pérez Galván, A., Phillips, D.G., Picker, R., Pitt, M.L., Plaster, B., Ramsey, J.C., Rios, R., Salvat, D.J., Saunders, A., Sondheim, W., Seestrom, S.J., Sjue, S., Slutsky, S., Sun, X., Swank, C., Swift, G., Tatar, E., Vogelaar, R.B., Vorndick, B., Wang, Z., Wexler, J., Womack, T., Wrede, C., Young, A.R., Zeck, B.A., Institut Laue-Langevin (ILL), ILL, UCNA, and Institut Laue-Langevin ( ILL )

Subjects
electron, axial-vector, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], weak coupling, Automatic Keywords, statistics, S017AV, correlation, High Energy Physics::Experiment, [ PHYS.NEXP ] Physics [physics]/Nuclear Experiment [nucl-ex], Nuclear Experiment, n: spin, S017BA, asymmetry, experimental results
Abstract

The neutron $\beta$-decay asymmetry parameter $A_0$ defines the correlation between the spin of the neutron and the momentum of the emitted electron, which determines $\lambda=\frac{g_{A}}{g_{V}}$, the ratio of the axial-vector to vector weak coupling constants. The UCNA Experiment, located at the Ultracold Neutron facility at the Los Alamos Neutron Science Center, is the first to measure such a correlation coefficient using ultracold neutrons (UCN). Following improvements to the systematic uncertainties and increased statistics, we report the new result $A_0 = -0.12054(44)_{\mathrm{stat}}(68)_{\mathrm{syst}}$ which yields $\lambda\equiv \frac{g_{A}}{g_{V}}=-1.2783(22)$. Combination with the previous UCNA result and accounting for correlated systematic uncertainties produces $A_0=-0.12015(34)_{\mathrm{stat}}(63)_{\mathrm{syst}}$ and $\lambda\equiv \frac{g_{A}}{g_{V}}=-1.2772(20)$., Comment: 9 pages, 7 figures, updated to as-published version

Published
2018

35. Search for dark matter decay of the free neutron from the UCNA experiment: n $\rightarrow ��+ e^+e^-$

Author

Sun, X., Adamek, E., Allgeier, B., Blatnik, M., Bowles, T. J., Broussard, L. J., Brown, M. A. -P., Carr, R., Clayton, S., Cude-Woods, C., Currie, S., Dees, E. B., Ding, X., Filippone, B. W., Garc��a, A., Geltenbort, P., Hasan, S., Hickerson, K. P., Hoagland, J., Hong, R., Hogan, G. E., Holley, A. T., Ito, T. M., Knecht, A., Liu, C. -Y., Liu, J., Makela, M., Mammei, R., Martin, J. W., Melconian, D., Mendenhall, M. P., Moore, S. D., Morris, C. L., Nepal, S., Nouri, N., Pattie, R. W., Galv��n, A. P��rez, Phillips, D. G., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Salvat, D. J., Saunders, A., Sondheim, W., Sjue, S., Slutsky, S., Swank, C., Swift, G., Tatar, E., Vogelaar, R. B., VornDick, B., Wang, Z., Wei, W., Wexler, J., Womack, T., Wrede, C., Young, A. R., and Zeck, B. A.

Subjects
FOS: Physical sciences, High Energy Physics::Experiment, Instrumentation and Detectors (physics.ins-det), Nuclear Experiment (nucl-ex)
Abstract

It has been proposed recently that a previously unobserved neutron decay branch to a dark matter particle ($��$) could account for the discrepancy in the neutron lifetime observed in experiments that use two different measurement techniques. One of the possible final states discussed includes a single $��$ along with an $e^{+}e^{-}$ pair. We use data from the UCNA (Ultracold Neutron Asymmetry) experiment to set limits on this decay channel. Coincident electron-like events are detected with $\sim 4��$ acceptance using a pair of detectors that observe a volume of stored Ultracold Neutrons (UCNs). The summed kinetic energy ($E_{e^{+}e^{-}}$) from such events is used to set limits, as a function of the $��$ mass, on the branching fraction for this decay channel. For $��$ masses consistent with resolving the neutron lifetime discrepancy, we exclude this as the dominant dark matter decay channel at $\gg~5��$ level for $100~\text{keV} < E_{e^{+}e^{-}} < 644~\text{keV}$. If the $��+e^{+}e^{-}$ final state is not the only one, we set limits on its branching fraction of $< 10^{-4}$ for the above $E_{e^{+}e^{-}}$ range at $> 90\%$ confidence level., 5 pages, 5 figures

Published
2018
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36. Fast-switching magnet serving a spallation-driven ultracold neutron source

Author

Ahmed, S., primary, Altiere, E., additional, Andalib, T., additional, Barnes, M. J., additional, Bell, B., additional, Bidinosti, C. P., additional, Bylinsky, Y., additional, Chak, J., additional, Das, M., additional, Davis, C. A., additional, Fischer, F., additional, Franke, B., additional, Gericke, M. T. W., additional, Giampa, P., additional, Hahn, M., additional, Hansen-Romu, S., additional, Hatanaka, K., additional, Hayamizu, T., additional, Jamieson, B., additional, Jones, D., additional, Katsika, K., additional, Kawasaki, S., additional, Kikawa, T., additional, Klassen, W., additional, Konaka, A., additional, Korkmaz, E., additional, Kuchler, F., additional, Kurchaninov, L., additional, Lang, M., additional, Lee, L., additional, Lindner, T., additional, Madison, K. W., additional, Mammei, J., additional, Mammei, R., additional, Martin, J. W., additional, Matsumiya, R., additional, Miller, E., additional, Momose, T., additional, Picker, R., additional, Pierre, E., additional, Ramsay, W. D., additional, Rao, Y.-N., additional, Rawnsley, W. R., additional, Rebenitsch, L., additional, Schreyer, W., additional, Sidhu, S., additional, Vanbergen, S., additional, van Oers, W. T. H., additional, Watanabe, Y. X., additional, and Yosifov, D., additional

Published
2019
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37. A beamline for fundamental neutron physics at TRIUMF

Author

Ahmed, S., primary, Andalib, T., additional, Barnes, M.J., additional, Bidinosti, C.B., additional, Bylinsky, Y., additional, Chak, J., additional, Das, M., additional, Davis, C.A., additional, Franke, B., additional, Gericke, M.T.W., additional, Giampa, P., additional, Hahn, M., additional, Hansen-Romu, S., additional, Hatanaka, K., additional, Jamieson, B., additional, Jones, D., additional, Katsika, K., additional, Kawasaki, S., additional, Klassen, W., additional, Konaka, A., additional, Korkmaz, E., additional, Kuchler, F., additional, Kurchaninov, L., additional, Lang, M., additional, Lee, L., additional, Lindner, T., additional, Madison, K.W., additional, Mammei, J., additional, Mammei, R., additional, Martin, J.W., additional, Matsumiya, R., additional, Picker, R., additional, Pierre, E., additional, Ramsay, W.D., additional, Rao, Y.-N., additional, Rawnsley, W.R., additional, Rebenitsch, L., additional, Remon, C.A., additional, Schreyer, W., additional, Sikora, A., additional, Sidhu, S., additional, Sonier, J., additional, Thorsteinson, B., additional, Vanbergen, S., additional, van Oers, W.T.H., additional, Watanabe, Y.X., additional, and Yosifov, D., additional

Published
2019
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38. Final results for the neutron β-asymmetry parameter A0 from the UCNA experiment

Author

Plaster, B., primary, Adamek, E., additional, Allgeier, B., additional, Anaya, J., additional, Back, H.O., additional, Bagdasarova, Y., additional, Berguno, D.B., additional, Blatnik, M., additional, Boissevain, J.G., additional, Bowles, T.J., additional, Broussard, L.J., additional, Brown, M.A.-P., additional, Carr, R., additional, Clark, D.J., additional, Clayton, S., additional, Cude-Woods, C., additional, Currie, S., additional, Dees, E.B., additional, Ding, X., additional, Du, S., additional, Filippone, B.W., additional, García, A., additional, Geltenbort, P., additional, Hasan, S., additional, Hawari, A., additional, Hickerson, K.P., additional, Hill, R., additional, Hino, M., additional, Hoagland, J., additional, Hoedl, S.A., additional, Hogan, G.E., additional, Hona, B., additional, Hong, R., additional, Holley, A.T., additional, Ito, T.M., additional, Kawai, T., additional, Kirch, K., additional, Kitagaki, S., additional, Knecht, A., additional, Lamoreaux, S.K., additional, Liu, C.-Y., additional, Liu, J., additional, Makela, M., additional, Mammei, R.R., additional, Martin, J.W., additional, Meier, N., additional, Melconian, D., additional, Mendenhall, M.P., additional, Moore, S.D., additional, Morris, C.L., additional, Mortensen, R., additional, Nepal, S., additional, Nouri, N., additional, Pattie, R.W., additional, Pérez Galván, A., additional, Phillips II, D.G., additional, Pichlmaier, A., additional, Picker, R., additional, Pitt, M.L., additional, Ramsey, J.C., additional, Rios, R., additional, Russell, R., additional, Sabourov, K., additional, Sallaska, A.L., additional, Salvat, D.J., additional, Saunders, A., additional, Schmid, R., additional, Seestrom, S.J., additional, Servicky, C., additional, Sharapov, E.I., additional, Sjue, S.K.L., additional, Slutsky, S., additional, Smith, D., additional, Sondheim, W.E., additional, Sun, X., additional, Swank, C., additional, Swift, G., additional, Tatar, E., additional, Teasdale, W., additional, Terai, C., additional, Tipton, B., additional, Utsuro, M., additional, Vogelaar, R.B., additional, VornDick, B., additional, Wang, Z., additional, Wehring, B., additional, Wexler, J., additional, Womack, T., additional, Wrede, C., additional, Xu, Y.P., additional, Yan, H., additional, Young, A.R., additional, Yuan, J., additional, and Zeck, B.A., additional

Published
2019
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39. The TRIUMF UltraCold Advanced Neutron Source.

Author

Martin, Jeff, Franke, B., Hatanaka, K., Kawasaki, S., and Picker, R.

Subjects
NUCLEAR research, ELECTROWEAK interactions, CYCLOTRONS, ELECTRIC dipole moments, CP violation, NEUTRON counters, ULTRACOLD neutrons
Published
2021
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40. First direct constraints on Fierz interference in free-neutron β decay

Author

Hickerson, K. P., Sun, X., Carr, R., Filippone, B. W., Liu, J. L., Mendenhall, M. P., Pérez Galván, A., and Picker, R.

Subjects
Astrophysics::High Energy Astrophysical Phenomena, High Energy Physics::Experiment, Nuclear Experiment
Abstract

Precision measurements of free-neutron β decay have been used to precisely constrain our understanding of the weak interaction. However, the neutron Fierz interference term b_n, which is particularly sensitive to beyond-standard-model tensor currents at the TeV scale, has thus far eluded measurement. Here we report the first direct constraints on this term, finding b_n=0.067±0.005_(stat)^(+0.090)_(−0.061)_(sys), consistent with the standard model. The uncertainty is dominated by absolute energy reconstruction and the linearity of the β spectrometer energy response.

Published
2017

41. First direct constraints on Fierz interference in free neutron $\beta$ decay

Author

Hickerson, K.P., Sun, X., Bagdasarova, Y., Bravo-Berguño, D., Broussard, L.J., Brown, P., Carr, R., Currie, S., Ding, X., Filippone, B.W., GarcÍa, A., Geltenbort, P., Hoagland, J., Holley, A.T., Hong, R., Ito, T.M., Knecht, A., Liu, C.-Y, Liu, J.L., Makela, M., Mammei, R.R., Martin, J.W., Melconian, D., Mendenhall, M.P., Moore, § S.D., Morris, C.L., Pattie, R.W., Pérez Galván, A., Picker, R., Pitt, M.L., Plaster, B., Ramsey, J.C., Rios, R., Saunders, A., Seestrom, S.J., Sharapov, E.I., Sondheim, W.E., Tatar, E., Vogelaar, R.B., Vorndick, B., Wrede, C., Young, A.R., Zeck, B.A., Institut Laue-Langevin (ILL), ILL, and Institut Laue-Langevin ( ILL )

Subjects
Particle physics, scale: TeV, Astrophysics::High Energy Astrophysical Phenomena, interference, n: decay, Weak interaction, [PHYS.NEXP]Physics [physics]/Nuclear Experiment [nucl-ex], Interference (wave propagation), 01 natural sciences, Standard Model, Nuclear physics, weak interaction, statistical analysis, 0103 physical sciences, Fierz-Pauli equation, Neutron, Tensor, [ PHYS.NEXP ] Physics [physics]/Nuclear Experiment [nucl-ex], 010306 general physics, Nuclear Experiment, Monte Carlo, Physics, Spectrometer, 010308 nuclear & particles physics, precision measurement, new physics, n: decay rate, Electroweak interaction, semileptonic decay, coupling: tensor, Beta decay, High Energy Physics::Experiment, spectrometer, experimental results
Abstract

Precision measurements of free neutron $\beta$-decay have been used to precisely constrain our understanding of the weak interaction. However the neutron Fierz interference term $b_n$, which is particularly sensitive to Beyond-Standard-Model tensor currents at the TeV scale, has thus far eluded measurement. Here we report the first direct constraints on this term, finding $b_n = 0.067 \pm 0.005_{\text{stat}} {}^{+0.090}_{- 0.061}{}_{\text{sys}}$, consistent with the Standard Model. The uncertainty is dominated by absolute energy reconstruction and the linearity of the beta spectrometer energy response.

Published
2017

44. Neutron decay correlations in the Nab experiment

Author

Broussard, L. J., primary, Alarcon, R., additional, Baeßler, S, additional, Barrón Palos, L., additional, Birge, N., additional, Bode, T., additional, Bowman, J. D., additional, Brunst, T., additional, Calarco, J. R., additional, Caylor, J., additional, Chupp, T., additional, Cianciolo, V., additional, Crawford, C., additional, Dodson, G. W., additional, DuBois, J., additional, Fan, W., additional, Farrar, W., additional, Fomin, N., additional, Frlež, E., additional, Fry, J., additional, Gericke, M. T., additional, Glück, F., additional, Greene, G. L., additional, Grzywacz, R. K., additional, Gudkov, V., additional, Hendrus, C., additional, Hersman, F. W., additional, Ito, T., additional, Li, H., additional, Macsai, N., additional, Makela, M. F., additional, Mammei, J., additional, Mammei, R., additional, Martin, J., additional, Martinez, M., additional, McGaughey, P. L., additional, Mertens, S., additional, Mirabal-Martinez, J., additional, Mueller, P., additional, Page, S. A., additional, Penttilä, S. I., additional, Picker, R., additional, Plaster, B., additional, Počanić, D., additional, Radford, D. C., additional, Ramsey, J., additional, Rykaczewski, K. P., additional, Salas-Bacci, A., additional, Scott, E. M., additional, Sjue, S. K. L., additional, Smith, A., additional, Smith, E., additional, Sprow, A., additional, Stevens, E., additional, Wexler, J., additional, Whitehead, R., additional, Wilburn, W. S., additional, Young, A. R., additional, and Zeck, B. A., additional

Published
2017
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47. Precision measurement of the neutron beta-decay asymmetry

Author

Mendenhall, M. P., Pattie, R. W., Bagdasarova, Y., Berguno, D. B., Broussard, L. J., Carr, Rachel E., Currie, S., Ding, X., Filippone, B. W., Garcia, A., Geltenbort, P., Hickerson, K. P., Hoagland, J., Holley, A. T., Hong, R., Ito, T. M., Knecht, A., Liu, C. Y., Liu, J. L., Makela, M., Mammei, R. R., Martin, J. W., Melconian, D., Moore, S. D., Morris, C. L., Galvan, A. P., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Saunders, A., Seestrom, S. J., Sharapov, E. I., Sondheim, W. E., Tatar, E., Vogelaar, R. Bruce, VornDick, B., Wrede, C., Young, A. R., Zeck, B. A., Ucna Collaboration, Mendenhall, M. P., Pattie, R. W., Bagdasarova, Y., Berguno, D. B., Broussard, L. J., Carr, Rachel E., Currie, S., Ding, X., Filippone, B. W., Garcia, A., Geltenbort, P., Hickerson, K. P., Hoagland, J., Holley, A. T., Hong, R., Ito, T. M., Knecht, A., Liu, C. Y., Liu, J. L., Makela, M., Mammei, R. R., Martin, J. W., Melconian, D., Moore, S. D., Morris, C. L., Galvan, A. P., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Saunders, A., Seestrom, S. J., Sharapov, E. I., Sondheim, W. E., Tatar, E., Vogelaar, R. Bruce, VornDick, B., Wrede, C., Young, A. R., Zeck, B. A., and Ucna Collaboration

Abstract

A new measurement of the neutron beta-decay asymmetry A(0) has been carried out by the UCNA Collaboration using polarized ultracold neutrons (UCNs) from the solid deuterium UCN source at the Los Alamos Neutron Science Center. Improvements in the experiment have led to reductions in both statistical and systematic uncertainties leading to A(0) = -0.11954(55)(stat)(98)(syst), corresponding to the ratio of axial-vector to vector coupling lambda = g(A)/g(V) = -1.2756(30).

Published
2013
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48. Precision measurement of the neutron beta-decay asymmetry

Author

Physics, Mendenhall, M. P., Pattie, R. W., Bagdasarova, Y., Berguno, D. B., Broussard, L. J., Carr, Rachel E., Currie, S., Ding, X., Filippone, B. W., Garcia, A., Geltenbort, P., Hickerson, K. P., Hoagland, J., Holley, A. T., Hong, R., Ito, T. M., Knecht, A., Liu, C. Y., Liu, J. L., Makela, M., Mammei, R. R., Martin, J. W., Melconian, D., Moore, S. D., Morris, C. L., Galvan, A. P., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Saunders, A., Seestrom, S. J., Sharapov, E. I., Sondheim, W. E., Tatar, E., Vogelaar, R. Bruce, VornDick, B., Wrede, C., Young, A. R., Zeck, B. A., Ucna Collaboration, Physics, Mendenhall, M. P., Pattie, R. W., Bagdasarova, Y., Berguno, D. B., Broussard, L. J., Carr, Rachel E., Currie, S., Ding, X., Filippone, B. W., Garcia, A., Geltenbort, P., Hickerson, K. P., Hoagland, J., Holley, A. T., Hong, R., Ito, T. M., Knecht, A., Liu, C. Y., Liu, J. L., Makela, M., Mammei, R. R., Martin, J. W., Melconian, D., Moore, S. D., Morris, C. L., Galvan, A. P., Picker, R., Pitt, M. L., Plaster, B., Ramsey, J. C., Rios, R., Saunders, A., Seestrom, S. J., Sharapov, E. I., Sondheim, W. E., Tatar, E., Vogelaar, R. Bruce, VornDick, B., Wrede, C., Young, A. R., Zeck, B. A., and Ucna Collaboration

Abstract

A new measurement of the neutron beta-decay asymmetry A(0) has been carried out by the UCNA Collaboration using polarized ultracold neutrons (UCNs) from the solid deuterium UCN source at the Los Alamos Neutron Science Center. Improvements in the experiment have led to reductions in both statistical and systematic uncertainties leading to A(0) = -0.11954(55)(stat)(98)(syst), corresponding to the ratio of axial-vector to vector coupling lambda = g(A)/g(V) = -1.2756(30).

Published
2013

49. Precision measurement of the neutronβ-decay asymmetry

Author

Mendenhall, M. P., primary, Pattie, R. W., additional, Bagdasarova, Y., additional, Berguno, D. B., additional, Broussard, L. J., additional, Carr, R., additional, Currie, S., additional, Ding, X., additional, Filippone, B. W., additional, García, A., additional, Geltenbort, P., additional, Hickerson, K. P., additional, Hoagland, J., additional, Holley, A. T., additional, Hong, R., additional, Ito, T. M., additional, Knecht, A., additional, Liu, C.-Y., additional, Liu, J. L., additional, Makela, M., additional, Mammei, R. R., additional, Martin, J. W., additional, Melconian, D., additional, Moore, S. D., additional, Morris, C. L., additional, Pérez Galván, A., additional, Picker, R., additional, Pitt, M. L., additional, Plaster, B., additional, Ramsey, J. C., additional, Rios, R., additional, Saunders, A., additional, Seestrom, S. J., additional, Sharapov, E. I., additional, Sondheim, W. E., additional, Tatar, E., additional, Vogelaar, R. B., additional, VornDick, B., additional, Wrede, C., additional, Young, A. R., additional, and Zeck, B. A., additional

Published
2013
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