Your search keyword '"O'Shaughnessy, C. M."' showing total 5 results

1. Cerium doped yttrium aluminum perovskite scintillator as an absolute ultracold neutron detector.

Author

Krivoš M, Floyd NC, Tang Z, Morris CL, Blatnik M, Clayton SM, Cude-Woods CB, Holley AT, Hooks DE, Ito TM, Liu CY, Makela M, Martinez IF, Martinez MR, Navazo ASC, O'Shaughnessy CM, Pattie RW, Renner EL, Singh M, Surbrook J, and Young AR

Abstract

The upcoming UCNProBe experiment at Los Alamos National Laboratory will measure the beta decay rate of free neutrons with different systematic uncertainties than previous beam-based neutron lifetime experiments. We have tested a new 10B-coated Yttrium Aluminum Perovskite (YAP:Ce) scintillator and present its properties. The advantages of the YAP:Ce scintillator include its high Fermi potential, which reduces the probability for upscattering of ultracold neutrons (UCN), and its short decay time, which increases sensitivity at high counting rates. Birks' coefficient of YAP:Ce was measured to be (5.56-0.30+0.05)×10-4 cm/MeV. The loss of light due to the 120 nm 10B-coating was measured to be about 60%, and the loss of light from YAP:Ce due to transmission through a deuterated polystyrene scintillator was about 50%. The efficiency for neutron capture on the 10B coating was (86.8 ± 2.6)%, and a measurement using UCN showed that the YAP:Ce crystal counted 8%-28% more UCN compared to a ZnS:Ag screen. The difference may be due to the uneven coating of 10B on the rough surface of ZnS:Ag., (© 2024 Author(s). All article content, except where otherwise noted, is licensed under a Creative Commons Attribution-NonCommercial 4.0 International (CC BY-NC) license (https://creativecommons.org/licenses/by-nc/4.0/).)

Published

2024

2. Scintillation characteristics of the EJ-299-02H scintillator.

Author

Floyd N, Hassan MT, Tang Z, Krivoš M, Blatnik M, Cude-Woods C, Clayton SM, Holley AT, Ito TM, Johnson BA, Liu CY, Makela M, Morris CL, Navazo ASC, O'Shaughnessy CM, Renner EL, Pattie RW, and Young AR

Abstract

A study of the dead layer thickness and quenching factor of a plastic scintillator for use in ultracold neutron (UCN) experiments is described. Alpha spectroscopy was used to determine the thickness of a thin surface dead layer to be 630 ± 110 nm. The relative light outputs from the decay of 241Am and Compton scattering of electrons were used to extract Birks' law coefficient, yielding a kB value of 0.087 ± 0.003 mm/MeV, consistent with some previous reports for other polystyrene-based scintillators. The results from these measurements are incorporated into the simulation to show that an energy threshold of (∼9 keV) can be achieved for the UCNProBe experiment. This low threshold enables high beta particle detection efficiency and the indirect measurement of UCN. The ability to make the scintillator deuterated, accompanied by its relatively thin dead layer, gives rise to unique applications in a wide range of UCN experiments, where it can be used to trap UCN and detect charged particles in situ., (© 2024 Author(s). Published under an exclusive license by AIP Publishing.)

Published

2024

3. Ultracold neutron properties of the Eljen-299-02D deuterated scintillator.

Author

Tang Z, Watkins EB, Clayton SM, Currie SA, Fellers DE, Hassan MT, Hooks DE, Ito TM, Lawrence SK, MacDonald SWT, Makela M, Morris CL, Neukirch LP, Saunders A, O'Shaughnessy CM, Cude-Woods C, Choi JH, Young AR, Zeck BA, Gonzalez F, Liu CY, Floyd NC, Hickerson KP, Holley AT, Johnson BA, Lambert JC, and Pattie RW

Abstract

In this paper, we report studies of the Fermi potential and loss per bounce of ultracold neutrons (UCNs) on a deuterated scintillator (Eljen-299-02D). These UCN properties of the scintillator enable its use in a wide variety of applications in fundamental neutron research.

Published

2021

4. Search for the Neutron Decay n→X+γ, Where X is a Dark Matter Particle.

Author

Tang Z, Blatnik M, Broussard LJ, Choi JH, Clayton SM, Cude-Woods C, Currie S, Fellers DE, Fries EM, Geltenbort P, Gonzalez F, Hickerson KP, Ito TM, Liu CY, MacDonald SWT, Makela M, Morris CL, O'Shaughnessy CM, Pattie RW, Plaster B, Salvat DJ, Saunders A, Wang Z, Young AR, and Zeck BA

Abstract

Fornal and Grinstein recently proposed that the discrepancy between two different methods of neutron lifetime measurements, the beam and bottle methods, can be explained by a previously unobserved dark matter decay mode, n→X+γ. We perform a search for this decay mode over the allowed range of energies of the monoenergetic γ ray for X to be dark matter. A Compton-suppressed high-purity germanium detector is used to identify γ rays from neutron decay in a nickel-phosphorous-coated stainless-steel bottle. A combination of Monte Carlo and radioactive source calibrations is used to determine the absolute efficiency for detecting γ rays arising from the dark matter decay mode. We exclude the possibility of a sufficiently strong branch to explain the lifetime discrepancy with 97% confidence.

Published

2018

5. Invited article: development of high-field superconducting Ioffe magnetic traps.

Author

Yang L, Brome CR, Butterworth JS, Dzhosyuk SN, Mattoni CE, McKinsey DN, Michniak RA, Doyle JM, Golub R, Korobkina E, O'Shaughnessy CM, Palmquist GR, Seo PN, Huffman PR, Coakley KJ, Mumm HP, Thompson AK, Yang GL, and Lamoreaux SK

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