Your search keyword '"Sweany, M."' showing total 153 results

1. A comparison of the neutron detection efficiency and response characteristics of two pixelated PSD-capable organic scintillator detectors with different photo-detection readout methods

Author

Balajthy, J., Marleau, P., and Sweany, M.

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment

Abstract

We characterize the performance of two pixelated neutron detectors: a PMT-based array that utilizes Anger logic for pixel identification and a SiPM-based array that employs individual pixel readout. The SiPM-based array offers improved performance over the previously developed PMT-based detector both in terms of uniformity and neutron detection efficiency. Each detector array uses PSD-capable plastic scintillator as a detection medium. We describe the calibration and neutron efficiency measurement of both detectors using a $^{137}$Cs source for energy calibration and a $^{252}$Cf source for calibration of the neutron response. We find that the intrinsic neutron detection efficiency of the SiPM-based array is ($30.2 \ \pm \ 1.7$)\%, which is almost twice that of the PMT-based array, which we measure to be ($16.9 \pm 0.2$)\%.

Published

2023

2. Design and Calibration of an Optically Segmented Single Volume Scatter Camera for Neutron Imaging

Author

Galindo-Tellez, A., Keefe, K., Adamek, E., Brubaker, E., Crow, B., Dorrill, R., Druetzler, A., Felix, C. J., Kaneshige, N., Learned, J. G., Manfredi, J. J., Nishimura, K., Souza, B. Pinto, Schoen, D., and Sweany, M.

Subjects

Physics - Instrumentation and Detectors

Abstract

The Optically Segmented Single Volume Scatter Camera (OS-SVSC) aims to image neutron sources for non-proliferation applications using the kinematic reconstruction of elastic double-scatter events. Our prototype system consists of 64 EJ-204 organic plastic scintillator bars, each measuring 5 mm $\times$ 5 mm $\times$ 200 mm and individually wrapped in Teflon tape. The scintillator array is optically coupled to two silicon photomultiplier ArrayJ-60035 64P-PCB arrays, each comprised of 64 individual 6 $\times$ 6 mm J-Series sensors arranged in an 8 $\times$ 8 array. We detail our calibration efforts, beginning with calibrations for the electronics, based on the IRS3D application-specific integrated circuits, and their associated timing resolutions, ranging from 30 ps to 90 ps. With electronics calibrations applied, energy and position calibrations were performed for a set of edge bars using $^{22}$Na and $^{90}$Sr, respectively, reporting an average resolution of (12.07$\pm$0.03) mm for energy depositions between 900 keVee and 1000 keVee. We further demonstrate a position calibration method for the internal bars of the matrix using cosmic-ray muons as an alternative to emission sources that cannot easily access these bars, with an average measured resolution of (14.86$\pm$0.29) mm for depositions between 900 keVee and 1000 keVee. The coincident time resolution reported between pairs of bars measured up to 400 ps from muon acquisitions. Energy and position calibration values measured with muons are consistent with those obtained using particle emission sources., Comment: 24 pages, 32 figures. Manuscript submitted to Jinst

Published

2021

3. Source detection at 100 meter standoff with a time-encoded imaging system

Author

Brennan, J., Brubaker, E., Gerling, M., Marleau, P., Monterial, M., Nowack, A., Schuster, P., Sturm, B., and Sweany, M.

Subjects

Physics - Instrumentation and Detectors

Abstract

We present the design, characterization, and testing of a laboratory prototype radiological search and localization system. The system, based on time-encoded imaging, uses the attenuation signature of neutrons in time, induced by the geometrical layout and motion of the system. We have demonstrated the ability to detect a ~1 mCi Cf-252 radiological source at 100 m standoff with 90% detection efficiency and 10% false positives against background in 12 min. This same detection efficiency is met at 15 s for a 40 m standoff, and 1.2 s for a 20 m standoff., Comment: 9 pages, 15 figures, submitted to Nuclear Inst. and Methods in Physics Research, A

Published

2017

4. A comparison of the neutron detection efficiency and response characteristics of two pixelated PSD-capable organic scintillator detectors with different photo-detection readout methods

Author

Balajthy, J., primary, Marleau, P., additional, and Sweany, M., additional

Published

2024

5. A search for cosmogenic production of $\beta$-neutron emitting radionuclides in water

Author

Dazeley, S., Askins, M., Bergevin, M., Bernstein, A., Bowden, N. S., Jaffke, P., Rountree, S. D., Shokair, T. M., and Sweany, M.

Subjects

Nuclear Experiment, High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

Here we present the first results of WATCHBOY, a water Cherenkov detector designed to measure the yield of $\beta$-neutron emitting radionuclides produced by cosmic ray muons in water. In addition to the $\beta$-neutron measurement, we also provide a first look at isolating single-$\beta$ producing radionuclides following muon-induced hadronic showers as a check of the detection capabilities of WATCHBOY. The data taken over $207$ live days indicates a $^{9}$Li production yield upper limit of $1.9\times10^{-7}\mu^{-1}g^{-1}\mathrm{cm}^2$ at $\sim400$ meters water equivalent (m.w.e.) overburden at the $90\%$ confidence level. In this work the $^{9}$Li signal in WATCHBOY was used as a proxy for the combined search for $^{9}$Li and $^{8}$He production. This result will provide a constraint on estimates of antineutrino-like backgrounds in future water-based antineutrino detectors., Comment: 11 pages, 12 figures

Published

2015

6. The Physics and Nuclear Nonproliferation Goals of WATCHMAN: A WAter CHerenkov Monitor for ANtineutrinos

Author

Askins, M., Bergevin, M., Bernstein, A., Dazeley, S., Dye, S. T., Handler, T., Hatzikoutelis, A., Hellfeld, D., Jaffke, P., Kamyshkov, Y., Land, B. J., Learned, J. G., Marleau, P., Mauger, C., Gann, G. D. Orebi, Roecker, C., Rountree, S. D., Shokair, T. M., Smy, M. B., Svoboda, R., Sweany, M., Vagins, M. R., van Bibber, K. A., Vogelaar, R. B., Wetstein, M. J., and Yeh, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment, Nuclear Experiment

Abstract

This article describes the physics and nonproliferation goals of WATCHMAN, the WAter Cherenkov Monitor for ANtineutrinos. The baseline WATCHMAN design is a kiloton scale gadolinium-doped (Gd) light water Cherenkov detector, placed 13 kilometers from a civil nuclear reactor in the United States. In its first deployment phase, WATCHMAN will be used to remotely detect a change in the operational status of the reactor, providing a first- ever demonstration of the potential of large Gd-doped water detectors for remote reactor monitoring for future international nuclear nonproliferation applications. During its first phase, the detector will provide a critical large-scale test of the ability to tag neutrons and thus distinguish low energy electron neutrinos and antineutrinos. This would make WATCHMAN the only detector capable of providing both direction and flavor identification of supernova neutrinos. It would also be the third largest supernova detector, and the largest underground in the western hemisphere. In a follow-on phase incorporating the IsoDAR neutrino beam, the detector would have world-class sensitivity to sterile neutrino signatures and to non-standard electroweak interactions (NSI). WATCHMAN will also be a major, U.S. based integration platform for a host of technologies relevant for the Long-Baseline Neutrino Facility (LBNF) and other future large detectors. This white paper describes the WATCHMAN conceptual design,and presents the results of detailed simulations of sensitivity for the project's nonproliferation and physics goals. It also describes the advanced technologies to be used in WATCHMAN, including high quantum efficiency photomultipliers, Water-Based Liquid Scintillator (WbLS), picosecond light sensors such as the Large Area Picosecond Photo Detector (LAPPD), and advanced pattern recognition and particle identification methods., Comment: 35 pages, 9 figures

Published

2015

7. Characterization of a silicon photo-multiplier array with summing board as a photo-multiplier tube replacement in organic scintillator assemblies

Author

Sweany, M., Marleau, P., Allwork, C., Kallenbach, G., and Hammon, S.

Published

2020

8. Planning the Future of U.S. Particle Physics (Snowmass 2013): Chapter 8: Instrumentation Frontier

Author

Demarteau, M., Lipton, R., Nicholson, H., Shipsey, I., Akerib, D., Albayrak-Yetkin, A., Alexander, J., Anderson, J., Artuso, M., Asner, D., Ball, R., Battaglia, M., Bebek, C., Beene, J., Benhammou, Y., Bentefour, E., Bergevin, M., Bernstein, A., Bilki, B., Blucher, E., Bolla, G., Bortoletto, D., Bowden, N., Brooijmans, G., Byrum, K., Cabrera, B., Cancelo, G., Carlstrom, J., Casey, B., Chang, C., Chapman, J., Chen, C. H., Childres, I., Christian, D., Convery, M., Corso, W. Cooper J., Cumalat, J., Cushman, P., Da Via, C., Dazeley, S., Debbins, P., Deptuch, G., Dhawan, S., Di Benedetto, V., DiGiovene, B., Djurcic, Z., Dye, S., Elagin, A., Estrada, J., Evans, H., Etzion, E., Fast, J., Ferretti, C., Fisher, P., Fleming, B., Francis, K., Friedman, P., Frisch, H., Garcia-Sciveres, M., Gatto, C., Geronim, G., Gilchriese, G., Golwala, S., Grant, C., Grillo, A., Grünendahl, E., Gorham, P., Guan, L., Gutierrez, G., Haber, C., Hall, J., Haller, G., Hast, C., Heintz, U., Hemmick, T., Hitlin, D. G., Hogan, C., Hohlmann, M., Hoppe, E., Hsu, L., Huffer, M., Irwin, K., Izraelevitch, F., Jennings, G., Johnson, M., Jung, A., Kagan, H., Kenney, C., Kettell, S., Khanna, R., Khristenko, V., Krennrich, F., Kuehn, K., Kutschke, R., Learned, J., Lee, A. T., Levin, D., Liu, T., Liu, A. T. K., Lissauer, D., Love, J., Lynn, D., MacFarlane, D., Magill, S., Majewski, S., Mans, J., Maricic, J., Marleau, P., Mazzacane, A., McKinsey, D., Mehl, J., Mestvirisvilli, A., Meyer, S., Mokhov, N., Moshe, M., Mukherjee, A., Murat, P., Nahn, S., Narain, M., Nadel-Turonski, P., Newcomer, M., Nishimura, K., Nygren, D., Oberla, E., Onel, Y., Oreglia, M., Orrell, J., Paley, J., Para, A., Parker, S., Polychronakos, V., Pordes, S., Privitera, P., Prosser, A., Pyle, M., Raaf, J., Ramberg, E., Rameika, R., Rebel, B., Repond, J., Reyna, D., Ristori, L., Rivera, R., Ronzhin, A., Rusack, R., Russ, J., Ryd, A., Sadrozinski, H., Sahoo, H., Sanchez, M. C., Sanzeni, C., Schnetzer, S., Seidel, S., Seiden, A., Schmidt, I., Shenai, A., Shutt, T., Silver, Y., Smith, W., Snowden-Ifft, D., Sonnenschein, A., Southwick, D., Spiegel, L., Stanitzki, M., Striganov, S., Su, D., Sumner, R., Svoboda, R., Sweany, M., Talaga, R., Tayloe, R., Tentindo, S., Terentiev, N., Thom-Levy, J., Thorn, C., Tiffenberg, J., Trischuk, W., Tschirhart, R., Turner, M., Underwood, D., Uplegger, L., Urheim, J., Vagins, M., Van Bibber, K., Varner, G., Varner, R., Va'vra, J., Von der Lippe, H., Wagner, R., Wagner, S., Weaverdyck, C., Wenzel, H., Weinstein, A., Wetstein, M., White, A., Wigman, R., Wilson, P., Winn, D., Winter, P., Woody, C., Xia, L., Xie, J. Q., Ye, Z., Yeh, M. F., Yetkin, T., Yoo, J. H., Yu, J., Yu, J. M., Zeller, S., Zhang, J. L., Zhu, J. J., Zhou, B., Zhu, R. Y., and Zitzer, B.

Subjects

High Energy Physics - Experiment, High Energy Physics - Phenomenology, Physics - Instrumentation and Detectors

Abstract

These reports present the results of the 2013 Community Summer Study of the APS Division of Particles and Fields ("Snowmass 2013") on the future program of particle physics in the U.S. Chapter 8, on the Instrumentation Frontier, discusses the instrumentation needs of future experiments in the Energy, Intensity, and Cosmic Frontiers, promising new technologies for particle physics research, and issues of gathering resources for long-term research in this area., Comment: 50 pages

Published

2014

9. First results from the LUX dark matter experiment at the Sanford Underground Research Facility

Author

LUX Collaboration, Akerib, D. S., Araujo, H. M., Bai, X., Bailey, A. J., Balajthy, J., Bedikian, S., Bernard, E., Bernstein, A., Bolozdynya, A., Bradley, A., Byram, D., Cahn, S. B., Carmona-Benitez, M. C., Chan, C., Chapman, J. J., Chiller, A. A., Chiller, C., Clark, K., Coffey, T., Currie, A., Curioni, A., Dazeley, S., de Viveiros, L., Dobi, A., Dobson, J., Dragowsky, E. M., Druszkiewicz, E., Edwards, B., Faham, C. H., Fiorucci, S., Flores, C., Gaitskell, R. J., Gehman, V. M., Ghag, C., Gibson, K. R., Gilchriese, M. G. D., Hall, C., Hanhardt, M., Hertel, S. A., Horn, M., Huang, D. Q., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Knoche, R., Kyre, S., Lander, R., Larsen, N. A., Lee, C., Leonard, D. S., Lesko, K. T., Lindote, A., Lopes, M. I., Lyashenko, A., Malling, D. C., Mannino, R., McKinsey, D. N., Mei, D. -M., Mock, J., Moongweluwan, M., Morad, J., Morii, M., Murphy, A. St. J., Nehrkorn, C., Nelson, H., Neves, F., Nikkel, J. A., Ott, R. A., Pangilinan, M., Parker, P. D., Pease, E. K., Pech, K., Phelps, P., Reichhart, L., Shutt, T., Silva, C., Skulski, W., Sofka, C. J., Solovov, V. N., Sorensen, P., Stiegler, T., O`Sullivan, K., Sumner, T. J., Svoboda, R., Sweany, M., Szydagis, M., Taylor, D., Tennyson, B., Tiedt, D. R., Tripathi, M., Uvarov, S., Verbus, J. R., Walsh, N., Webb, R., White, J. T., White, D., Witherell, M. S., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Astrophysics - Cosmology and Extragalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment, Physics - Instrumentation and Detectors

Abstract

The Large Underground Xenon (LUX) experiment, a dual-phase xenon time-projection chamber operating at the Sanford Underground Research Facility (Lead, South Dakota), was cooled and filled in February 2013. We report results of the first WIMP search dataset, taken during the period April to August 2013, presenting the analysis of 85.3 live-days of data with a fiducial volume of 118 kg. A profile-likelihood analysis technique shows our data to be consistent with the background-only hypothesis, allowing 90% confidence limits to be set on spin-independent WIMP-nucleon elastic scattering with a minimum upper limit on the cross section of $7.6 \times 10^{-46}$ cm$^{2}$ at a WIMP mass of 33 GeV/c$^2$. We find that the LUX data are in strong disagreement with low-mass WIMP signal interpretations of the results from several recent direct detection experiments., Comment: Accepted by Phys. Rev. Lett. Appendix A included as supplementary material with PRL article

Published

2013

10. The Large Underground Xenon (LUX) Experiment

Author

Akerib, D. S., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Bolozdynya, A., Bradley, A., Byram, D., Cahn, S. B., Camp, C., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Chiller, A., Chiller, C., Clark, K., Classen, T., Coffey, T., Curioni, A., Dahl, E., Dazeley, S., de Viveiros, L., Dobi, A., Dragowsky, E., Druszkiewicz, E., Edwards, B., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Gilchriese, M., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Knoche, R., Kyre, S., Kwong, J., Lander, R., Larsen, N. A., Lee, C., Leonard, D. S., Lesko, K. T., Lindote, A., Lopes, M. I., Lyashenko, A., Malling, D. C., Mannino, R., Marquez, Z., McKinsey, D. N., Mei, D. -M., Mock, J., Moongweluwan, M., Morii, M., Nelson, H., Neves, F., Nikkel, J. A., Pangilinan, M., Parker, P. D., Pease, E. K., Pech, K., Phelps, P., Rodionov, A., Roberts, P., Shei, A., Shutt, T., Silva, C., Skulski, W., Solovov, V. N., Sofka, C. J., Sorensen, P., Spaans, J., Stiegler, T., Stolp, D., Svoboda, R., Sweany, M., Szydagis, M., Taylor, D., Thomson, J., Tripathi, M., Uvarov, S., Verbus, J. R., Walsh, N., Webb, R., White, D., White, J. T., Whitis, T. J., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

The Large Underground Xenon (LUX) collaboration has designed and constructed a dual-phase xenon detector, in order to conduct a search for Weakly Interacting Massive Particles(WIMPs), a leading dark matter candidate. The goal of the LUX detector is to clearly detect (or exclude) WIMPS with a spin independent cross section per nucleon of $2\times 10^{-46}$ cm$^{2}$, equivalent to $\sim$1 event/100 kg/month in the inner 100-kg fiducial volume (FV) of the 370-kg detector. The overall background goals are set to have $<$1 background events characterized as possible WIMPs in the FV in 300 days of running. This paper describes the design and construction of the LUX detector., Comment: 50 pages, 16 figures

Published

2012

11. Technical Results from the Surface Run of the LUX Dark Matter Experiment

Author

LUX Collaboration, Akerib, D. S., Bai, X., Bernard, E., Bernstein, A., Bradley, A., Byram, D., Cahn, S. B., Carmona-Benitez, M. C., Chapman, J. J., Coffey, T., Dobi, A., Dragowsky, E., Druszkiewicz, E., Edwards, B., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Gilchriese, M., Hall, C., Hanhardt, M., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Knoche, R., Larsen, N., Lee, C., Lesko, K. T., Lindote, A., Lopes, M. I., Lyashenko, A., Malling, D. C., Mannino, R., McKinsey, D. N., Mei, D., Mock, J., Moongweluwan, M., Morii, M., Nelson, H., Neves, F., Nikkel, J. A., Pangilinan, M., Pech, K., Phelps, P., Rodionov, A., Shutt, T., Silva, C., Skulski, W., Solovov, V. N., Sorensen, P., Stiegler, T., Sweany, M., Szydagis, M., Taylor, D., Tripathi, M., Uvarov, S., Verbus, J. R., de Viveiros, L., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment, High Energy Physics - Phenomenology, Physics - Instrumentation and Detectors

Abstract

We present the results of the three-month above-ground commissioning run of the Large Underground Xenon (LUX) experiment at the Sanford Underground Research Facility located in Lead, South Dakota, USA. LUX is a 370 kg liquid xenon detector that will search for cold dark matter in the form of Weakly Interacting Massive Particles (WIMPs). The commissioning run, conducted with the detector immersed in a water tank, validated the integration of the various sub-systems in preparation of the underground deployment. Using the data collected, we report excellent light collection properties, achieving 8.4 photoelectrons per keV for 662 keV electron recoils without an applied electric field, measured in the center of the WIMP target. We also find good energy and position resolution in relatively high-energy interactions from a variety of internal and external sources. Finally, we have used the commissioning data to tune the optical properties of our simulation and report updated sensitivity projections for spin-independent WIMP-nucleon scattering.

Published

2012

12. The LUX Prototype Detector: Heat Exchanger Development

Author

Akerib, D. S., Bai, X., Bedikian, S., Bernstein, A., Bolozdynya, A., Bradley, A., Cahn, S., Carr, D., Chapman, J. J., Clark, K., Classen, T., Curioni, A., Dahl, C. E., Dazeley, S., deViveiros, L., Dragowsky, M., Druszkiewicz, E., Fiorucci, S., Gaitskell, R. J., Hall, C., Faham, C., Holbrook, B., Kastens, L., Kazkaz, K., Kwong, J., Lander, R., Leonard, D., Malling, D., Mannino, R., McKinsey, D. N., Mei, D., Mock, J., Morii, M., Nikkel, J., Phelps, P., Shutt, T., Skulski, W., Sorensen, P., Spaans, J., Steigler, T., Svoboda, R., Sweany, M., Thomson, J., Tripathi, M., Walsh, N., Webb, R., White, J., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The LUX (Large Underground Xenon) detector is a two-phase xenon Time Projection Chamber (TPC) designed to search for WIMP-nucleon dark matter interactions. As with all noble element detectors, continuous purification of the detector medium is essential to produce a large ($>$1ms) electron lifetime; this is necessary for efficient measurement of the electron signal which in turn is essential for achieving robust discrimination of signal from background events. In this paper we describe the development of a novel purification system deployed in a prototype detector. The results from the operation of this prototype indicated heat exchange with an efficiency above 94% up to a flow rate of 42 slpm, allowing for an electron drift length greater than 1 meter to be achieved in approximately two days and sustained for the duration of the testing period., Comment: 12 pages, 9 figures

Published

2012

13. An Ultra-Low Background PMT for Liquid Xenon Detectors

Author

Akerib, D. S., Bai, X., Bernard, E., Bernstein, A., Bradley, A., Byram, D., Cahn, S. B., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Chan, Y-D., Clark, K., Coffey, T., deViveiros, L., Dragowsky, M., Druszkiewicz, E., Edwards, B., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Larsen, N., Lee, C., Lesko, K., Lindote, A., Lopes, M. I., Lyashenko, A., Malling, D. C., Mannino, R., McKinsey, D., Mei, D., Mock, J., Morii, M., Nelson, H., Neves, F., Nikkel, J. A., Pangilinan, M., Pech, K., Phelps, P., Shutt, T., Silva, C., Skulski, W., Solovov, V. N., Sorensen, P., Spaans, J., Stiegler, T., Sweany, M., Szydagis, M., Taylor, D., Thomson, J., Tripathi, M., Uvarov, S., Verbus, J. R., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Physics - Instrumentation and Detectors, Astrophysics - Instrumentation and Methods for Astrophysics, High Energy Physics - Experiment

Abstract

Results are presented from radioactivity screening of two models of photomultiplier tubes designed for use in current and future liquid xenon experiments. The Hamamatsu 5.6 cm diameter R8778 PMT, used in the LUX dark matter experiment, has yielded a positive detection of four common radioactive isotopes: 238U, 232Th, 40K, and 60Co. Screening of LUX materials has rendered backgrounds from other detector materials subdominant to the R8778 contribution. A prototype Hamamatsu 7.6 cm diameter R11410 MOD PMT has also been screened, with benchmark isotope counts measured at <0.4 238U / <0.3 232Th / <8.3 40K / 2.0+-0.2 60Co mBq/PMT. This represents a large reduction, equal to a change of \times 1/24 238U / \times 1/9 232Th / \times 1/8 40K per PMT, between R8778 and R11410 MOD, concurrent with a doubling of the photocathode surface area (4.5 cm to 6.4 cm diameter). 60Co measurements are comparable between the PMTs, but can be significantly reduced in future R11410 MOD units through further material selection. Assuming PMT activity equal to the measured 90% upper limits, Monte Carlo estimates indicate that replacement of R8778 PMTs with R11410 MOD PMTs will change LUX PMT electron recoil background contributions by a factor of \times1/25 after further material selection for 60Co reduction, and nuclear recoil backgrounds by a factor of \times 1/36. The strong reduction in backgrounds below the measured R8778 levels makes the R11410 MOD a very competitive technology for use in large-scale liquid xenon detectors., Comment: v2 updated to include content after reviewer comments (Sep 2012)

Published

2012

14. A Note on Neutron Capture Correlation Signals, Backgrounds, and Efficiencies

Author

Bowden, N. S., Sweany, M., and Dazeley, S.

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment

Abstract

A wide variety of detection applications exploit the timing correlations that result from the slowing and eventual capture of neutrons. These include capture-gated neutron spectrometry, multiple neutron counting for fissile material detection and identification, and antineutrino detection. There are several distinct processes that result in correlated signals in these applications. Depending on the application, one class of correlated events can be a background that is difficult to distinguish from the class that is of interest. Furthermore, the correlation timing distribution depends on the neutron capture agent and detector geometry. Here, we explain the important characteristics of the neutron capture timing distribution, making reference to simulations and data from a number of detectors currently in use or under development. We point out several features that may assist in background discrimination, and that must be carefully accounted for if accurate detection efficiencies are to be quoted., Comment: 7 pages, 7 figures; Submitted to Nuclear Instrument and Methods A

Published

2012

15. Radio-assay of Titanium samples for the LUX Experiment

Author

Akerib, D. S., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Bradley, A., Cahn, S. B., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Chan, Y-D., Clark, K., Classen, T., Coffey, T., Dazeley, S., deViveiros, L., Dragowsky, M., Druszkiewicz, E., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Lander, R., Larsen, N., Lee, C., Leonard, D., Lesko, K., Lyashenko, A., Malling, D. C., Mannino, R., McKinsey, D., Mei, D., Mock, J., Morii, M., Nelson, H., Nikkel, J. A., Pangilinan, M., Parker, P. D., Phelps, P., Shutt, T., Skulski, W., Sorensen, P., Spaans, J., Stiegler, T., Svoboda, R., Smith, A., Sweany, M., Szydagis, M., Thomson, J., Tripathi, M., Verbus, J. R., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., Uvarov, S., and Zhang, C.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment

Abstract

We report on the screening of samples of titanium metal for their radio-purity. The screening process described in this work led to the selection of materials used in the construction of the cryostats for the Large Underground Xenon (LUX) dark matter experiment. Our measurements establish titanium as a highly desirable material for low background experiments searching for rare events. The sample with the lowest total long-lived activity was measured to contain <0.25 mBq/kg of U-238, <0.2 mBq/kg of Th-232, and <1.2 mBq/kg of K-40. Measurements of several samples also indicated the presence of short-lived (84 day half life) Sc-46, likely produced cosmogenically via muon initiated (n,p) reactions., Comment: The LUX Collaboration

Published

2011

16. LUXSim: A Component-Centric Approach to Low-Background Simulations

Author

Akerib, D. S., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Bradley, A., Cahn, S. B., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Clark, K., Classen, T., Coffey, T., Dazeley, S., de Viveiros, L., Dragowsky, M., Druszkiewicz, E., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Lander, R., Larsen, N., Lee, C., Leonard, D., Lesko, K., Lyashenko, A., Malling, D. C., Mannino, R., McKinsey, D. N., Mei, D. -M, Mock, J., Morii, M., Nelson, H., Nikkel, J. A., Pangilinan, M., Parker, P. D., Phelps, P., Shutt, T., Skulski, W., Sorensen, P., Spaans, J., Stiegler, T., Svoboda, R., Sweany, M., Szydagis, M., Thomson, J., Tripathi, M., Verbus, J. R., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Physics - Data Analysis, Statistics and Probability, High Energy Physics - Experiment, Nuclear Experiment

Abstract

Geant4 has been used throughout the nuclear and high-energy physics community to simulate energy depositions in various detectors and materials. These simulations have mostly been run with a source beam outside the detector. In the case of low-background physics, however, a primary concern is the effect on the detector from radioactivity inherent in the detector parts themselves. From this standpoint, there is no single source or beam, but rather a collection of sources with potentially complicated spatial extent. LUXSim is a simulation framework used by the LUX collaboration that takes a component-centric approach to event generation and recording. A new set of classes allows for multiple radioactive sources to be set within any number of components at run time, with the entire collection of sources handled within a single simulation run. Various levels of information can also be recorded from the individual components, with these record levels also being set at runtime. This flexibility in both source generation and information recording is possible without the need to recompile, reducing the complexity of code management and the proliferation of versions. Within the code itself, casting geometry objects within this new set of classes rather than as the default Geant4 classes automatically extends this flexibility to every individual component. No additional work is required on the part of the developer, reducing development time and increasing confidence in the results. We describe the guiding principles behind LUXSim, detail some of its unique classes and methods, and give examples of usage. * Corresponding author, kareem@llnl.gov, Comment: 45 pages, 15 figures

Published

2011

17. Study of wavelength-shifting chemicals for use in large-scale water Cherenkov detectors

Author

Sweany, M., Bernstein, A., Dazeley, S., Dunmore, J., Felde, J., Svoboda, R., and Tripathi, M.

Subjects

Physics - Instrumentation and Detectors, Nuclear Experiment

Abstract

Cherenkov detectors employ various methods to maximize light collection at the photomultiplier tubes (PMTs). These generally involve the use of highly reflective materials lining the interior of the detector, reflective materials around the PMTs, or wavelength-shifting sheets around the PMTs. Recently, the use of water-soluble wavelength-shifters has been explored to increase the measurable light yield of Cherenkov radiation in water. These wave-shifting chemicals are capable of absorbing light in the ultravoilet and re-emitting the light in a range detectable by PMTs. Using a 250 L water Cherenkov detector, we have characterized the increase in light yield from three compounds in water: 4-Methylumbelliferone, Carbostyril-124, and Amino-G Salt. We report the gain in PMT response at a concentration of 1 ppm as: 1.88 $\pm$ 0.02 for 4-Methylumbelliferone, stable to within 0.5% over 50 days, 1.37 $\pm$ 0.03 for Carbostyril-124, and 1.20 $\pm$ 0.02 for Amino-G Salt. The response of 4-Methylumbelliferone was modeled, resulting in a simulated gain within 9% of the experimental gain at 1 ppm concentration. Finally, we report an increase in neutron detection performance of a large-scale (3.5 kL) gadolinium-doped water Cherenkov detector at a 4-Methylumbelliferone concentration of 1 ppm., Comment: 7 pages, 9 figures, Submitted to Nuclear Instruments and Methods A

Published

2011

18. After LUX: The LZ Program

Author

Malling, D. C., Akerib, D. S., Araujo, H. M., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Bradley, A., Cahn, S. B., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Clark, K., Classen, T., Coffey, T., Curioni, A., Currie, A., Dazeley, S., de Viveiros, L., Dragowsky, M., Druszkiewicz, E., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Lander, R., Larsen, N., Lee, C., Leonard, D., Lesko, K., Lindote, A., Lopes, M. I., Lyashenko, A., Majewski, P., Mannino, R., McKinsey, D. N., Mei, D. -M., Mock, J., Morii, M., Murphy, A. St J., Nelson, H., Neves, F., Nikkel, J. A., Pangilinan, M., Phelps, P., Reichhart, L., Shutt, T., Silva, C., Skulski, W., Solovov, V., Sorensen, P., Spaans, J., Stiegler, T., Sumner, T. J., Svoboda, R., Sweany, M., Szydagis, M., Thomson, J., Tripathi, M., Verbus, J. R., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics

Abstract

The LZ program consists of two stages of direct dark matter searches using liquid Xe detectors. The first stage will be a 1.5-3 tonne detector, while the last stage will be a 20 tonne detector. Both devices will benefit tremendously from research and development performed for the LUX experiment, a 350 kg liquid Xe dark matter detector currently operating at the Sanford Underground Laboratory. In particular, the technology used for cryogenics and electrical feedthroughs, circulation and purification, low-background materials and shielding techniques, electronics, calibrations, and automated control and recovery systems are all directly scalable from LUX to the LZ detectors. Extensive searches for potential background sources have been performed, with an emphasis on previously undiscovered background sources that may have a significant impact on tonne-scale detectors. The LZ detectors will probe spin-independent interaction cross sections as low as 5E-49 cm2 for 100 GeV WIMPs, which represents the ultimate limit for dark matter detection with liquid xenon technology., Comment: Conference proceedings from APS DPF 2011. 9 pages, 6 figures

Published

2011

19. Data Acquisition and Readout System for the LUX Dark Matter Experiment

Author

Akerib, D. S., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Bradley, A., Cahn, S. B., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Clark, K., Classen, T., Coffey, T., Curioni, A., Dazeley, S., deViveiros, L., Dragowsky, M., Druszkiewicz, E., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Lander, R., Larsen, N., Lee, C., Leonard, D., Lesko, K., Lyashenko, A., Malling, D. C., Mannino, R., McKinsey, D. N., Mei, D., Mock, J., Morii, M., Nelson, H., Nikkel, J. A., Pangilinan, M., Phelps, P., Shutt, T., Skulski, W., Sorensen, P., Spaans, J., Stiegler, T., Svoboda, R., Sweany, M., Szydagis, M., Thomson, J., Tripathi, M., Verbus, J. R., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., and Zhang, C.

Subjects

Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

LUX is a two-phase (liquid/gas) xenon time projection chamber designed to detect nuclear recoils from interactions with dark matter particles. Signals from the LUX detector are processed by custom-built analog electronics which provide properly shaped signals for the trigger and data acquisition (DAQ) systems. The DAQ is comprised of commercial digitizers with firmware customized for the LUX experiment. Data acquisition systems in rare-event searches must accommodate high rate and large dynamic range during precision calibrations involving radioactive sources, while also delivering low threshold for maximum sensitivity. The LUX DAQ meets these challenges using real-time baseline sup- pression that allows for a maximum event acquisition rate in excess of 1.5 kHz with virtually no deadtime. This paper describes the LUX DAQ and the novel acquisition techniques employed in the LUX experiment.

Published

2011

20. NEST: A Comprehensive Model for Scintillation Yield in Liquid Xenon

Author

Szydagis, M., Barry, N., Kazkaz, K., Mock, J., Stolp, D., Sweany, M., Tripathi, M., Uvarov, S., Walsh, N., and Woods, M.

Subjects

Physics - Instrumentation and Detectors

Abstract

A comprehensive model for explaining scintillation yield in liquid xenon is introduced. We unify various definitions of work function which abound in the literature and incorporate all available data on electron recoil scintillation yield. This results in a better understanding of electron recoil, and facilitates an improved description of nuclear recoil. An incident gamma energy range of O(1 keV) to O(1 MeV) and electric fields between 0 and O(10 kV/cm) are incorporated into this heuristic model. We show results from a Geant4 implementation, but because the model has a few free parameters, implementation in any simulation package should be simple. We use a quasi-empirical approach, with an objective of improving detector calibrations and performance verification. The model will aid in the design and optimization of future detectors. This model is also easy to extend to other noble elements. In this paper we lay the foundation for an exhaustive simulation code which we call NEST (Noble Element Simulation Technique)., Comment: 24 pages, 9 figures, 3 tables

Published

2011

21. Large-scale Gadolinium-doped Water Cerenkov Detector for Non-Proliferation

Author

Sweany, M., Bernstein, A., Bowden, N. S., Dazeley, S., Keefer, G., Svoboda, R., and Tripathi, M.

Subjects

Physics - Instrumentation and Detectors, High Energy Physics - Experiment, Nuclear Experiment

Abstract

Fission events from Special Nuclear Material (SNM), such as highly enriched uranium or plutonium, can produce simultaneous emission of multiple neutrons and high energy gamma-rays. The observation of time correlations between any of these particles is a significant indicator of the presence of fissionable material. Cosmogenic processes can also mimic these types of correlated signals. However, if the background is sufficiently low and fully characterized, significant changes in the correlated event rate in the presence of a target of interest constitutes a robust signature of the presence of SNM. Since fission emissions are isotropic, adequate sensitivity to these multiplicities requires a high efficiency detector with a large solid angle with respect to the target. Water Cerenkov detectors are a cost-effective choice when large solid angle coverage is required. In order to characterize the neutron detection performance of large-scale water Cerenkov detectors, we have designed and built a 3.5 kL water Cerenkov-based gamma-ray and neutron detector, and modeled the detector response in Geant4 [1]. We report the position-dependent neutron detection efficiency and energy response of the detector, as well as the basic characteristics of the simulation., Comment: 7 pages, 11 figures. Submitted to Nuclear Instruments and Methods in Physics Research A

Published

2011

22. Status of the LUX Dark Matter Search

Author

Fiorucci, S., Akerib, D. S., Bedikian, S., Bernstein, A., Bolozdynya, A., Bradley, A., Carr, D., Chapman, J., Clark, K., Classen, T., Curioni, A., Dahl, E., Dazeley, S., de Viveiros, L., Druszkiewicz, E., Gaitskell, R., Hall, C., Faham, C. Hernandez, Holbrook, B., Kastens, L., Kazkaz, K., Lander, R., Lesko, K., Malling, D., Mannino, R., McKinsey, D., Mei, D., Mock, J., Nikkel, J., Phelps, P., Schroeder, U., Shutt, T., Skulski, W., Sorensen, P., Spaans, J., Stiegler, T., Svoboda, R., Sweany, M., Thomson, J., Toke, J., Tripathi, M., Walsh, N., Webb, R., White, J., Wolfs, F., Woods, M., and Zhang, C.

Subjects

Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Instrumentation and Methods for Astrophysics

Abstract

The Large Underground Xenon (LUX) dark matter search experiment is currently being deployed at the Homestake Laboratory in South Dakota. We will highlight the main elements of design which make the experiment a very strong competitor in the field of direct detection, as well as an easily scalable concept. We will also present its potential reach for supersymmetric dark matter detection, within various timeframes ranging from 1 year to 5 years or more., Comment: 4 pages, in proceedings of the SUSY09 conference

Published

2009

23. First Results from the LUX Dark Matter Experiment at the Sanford Underground Research Facility

Author

Akerib, DS, Araújo, HM, Bai, X, Bailey, AJ, Balajthy, J, Bedikian, S, Bernard, E, Bernstein, A, Bolozdynya, A, Bradley, A, Byram, D, Cahn, SB, Carmona-Benitez, MC, Chan, C, Chapman, JJ, Chiller, AA, Chiller, C, Clark, K, Coffey, T, Currie, A, Curioni, A, Dazeley, S, de Viveiros, L, Dobi, A, Dobson, J, Dragowsky, EM, Druszkiewicz, E, Edwards, B, Faham, CH, Fiorucci, S, Flores, C, Gaitskell, RJ, Gehman, VM, Ghag, C, Gibson, KR, Gilchriese, MGD, Hall, C, Hanhardt, M, Hertel, SA, Horn, M, Huang, DQ, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Knoche, R, Kyre, S, Lander, R, Larsen, NA, Lee, C, Leonard, DS, Lesko, KT, Lindote, A, Lopes, MI, Lyashenko, A, Malling, DC, Mannino, R, McKinsey, DN, Mei, D-M, Mock, J, Moongweluwan, M, Morad, J, Morii, M, Murphy, A St J, Nehrkorn, C, Nelson, H, Neves, F, Nikkel, JA, Ott, RA, Pangilinan, M, Parker, PD, Pease, EK, Pech, K, Phelps, P, Reichhart, L, Shutt, T, Silva, C, Skulski, W, Sofka, CJ, Solovov, VN, Sorensen, P, Stiegler, T, O'Sullivan, K, Sumner, TJ, Svoboda, R, Sweany, M, Szydagis, M, Taylor, D, Tennyson, B, Tiedt, DR, Tripathi, M, Uvarov, S, Verbus, JR, Walsh, N, Webb, R, White, JT, White, D, Witherell, MS, Wlasenko, M, and Wolfs, FLH

Subjects

Nuclear and Plasma Physics, Particle and High Energy Physics, Physical Sciences, LUX Collaboration, astro-ph.CO, astro-ph.IM, hep-ex, physics.ins-det, Mathematical Sciences, Engineering, General Physics, Mathematical sciences, Physical sciences

Abstract

The Large Underground Xenon (LUX) experiment is a dual-phase xenon time-projection chamber operating at the Sanford Underground Research Facility (Lead, South Dakota). The LUX cryostat was filled for the first time in the underground laboratory in February 2013. We report results of the first WIMP search data set, taken during the period from April to August 2013, presenting the analysis of 85.3 live days of data with a fiducial volume of 118 kg. A profile-likelihood analysis technique shows our data to be consistent with the background-only hypothesis, allowing 90% confidence limits to be set on spin-independent WIMP-nucleon elastic scattering with a minimum upper limit on the cross section of 7.6 × 10(-46) cm(2) at a WIMP mass of 33 GeV/c(2). We find that the LUX data are in disagreement with low-mass WIMP signal interpretations of the results from several recent direct detection experiments.

Published

2014

24. Source detection at 100 meter standoff with a time-encoded imaging system

Author

Brennan, J., Brubaker, E., Gerling, M., Marleau, P., Monterial, M., Nowack, A., Schuster, P., Sturm, B., and Sweany, M.

Published

2018

25. Technical results from the surface run of the LUX dark matter experiment

Author

Akerib, DS, Bai, X, Bernard, E, Bernstein, A, Bradley, A, Byram, D, Cahn, SB, Carmona-Benitez, MC, Chapman, JJ, Coffey, T, Dobi, A, Dragowsky, E, Druszkiewicz, E, Edwards, B, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Gilchriese, M, Hall, C, Hanhardt, M, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Knoche, R, Larsen, N, Lee, C, Lesko, KT, Lindote, A, Lopes, MI, Lyashenko, A, Malling, DC, Mannino, R, McKinsey, DN, Mei, D, Mock, J, Moongweluwan, M, Morii, M, Nelson, H, Neves, F, Nikkel, JA, Pangilinan, M, Pech, K, Phelps, P, Rodionov, A, Shutt, T, Silva, C, Skulski, W, Solovov, VN, Sorensen, P, Stiegler, T, Sweany, M, Szydagis, M, Taylor, D, Tripathi, M, Uvarov, S, Verbus, JR, de Viveiros, L, Walsh, N, Webb, R, White, JT, Wlasenko, M, Wolfs, FLH, Woods, M, and Zhang, C

Subjects

Nuclear and Plasma Physics, Particle and High Energy Physics, Physical Sciences, Liquid xenon detectors, Dark matter, WIMP, Direct detection, astro-ph.IM, hep-ex, hep-ph, physics.ins-det, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Nuclear & Particles Physics, Astronomical sciences, Particle and high energy physics

Abstract

We present the results of the three-month above-ground commissioning run of the Large Underground Xenon (LUX) experiment at the Sanford Underground Research Facility located in Lead, South Dakota, USA. LUX is a 370 kg liquid xenon detector that will search for cold dark matter in the form of Weakly Interacting Massive Particles (WIMPs). The commissioning run, conducted with the detector immersed in a water tank, validated the integration of the various sub-systems in preparation for the underground deployment. Using the data collected, we report excellent light collection properties, achieving 8.4 photoelectrons per keV for 662 keV electron recoils without an applied electric field, measured in the center of the WIMP target. We also find good energy and position resolution in relatively high-energy interactions from a variety of internal and external sources. Finally, we have used the commissioning data to tune the optical properties of our simulation and report updated sensitivity projections for spin-independent WIMP-nucleon scattering. © 2013 Elsevier B.V. All rights reserved.

Published

2013

26. The Large Underground Xenon (LUX) experiment

Author

Akerib, DS, Bai, X, Bedikian, S, Bernard, E, Bernstein, A, Bolozdynya, A, Bradley, A, Byram, D, Cahn, SB, Camp, C, Carmona-Benitez, MC, Carr, D, Chapman, JJ, Chiller, A, Chiller, C, Clark, K, Classen, T, Coffey, T, Curioni, A, Dahl, E, Dazeley, S, de Viveiros, L, Dobi, A, Dragowsky, E, Druszkiewicz, E, Edwards, B, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Gilchriese, M, Hall, C, Hanhardt, M, Holbrook, B, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Knoche, R, Kyre, S, Kwong, J, Lander, R, Larsen, NA, Lee, C, Leonard, DS, Lesko, KT, Lindote, A, Lopes, MI, Lyashenko, A, Malling, DC, Mannino, R, Marquez, Z, McKinsey, DN, Mei, D-M, Mock, J, Moongweluwan, M, Morii, M, Nelson, H, Neves, F, Nikkel, JA, Pangilinan, M, Parker, PD, Pease, EK, Pech, K, Phelps, P, Rodionov, A, Roberts, P, Shei, A, Shutt, T, Silva, C, Skulski, W, Solovov, VN, Sofka, CJ, Sorensen, P, Spaans, J, Stiegler, T, Stolp, D, Svoboda, R, Sweany, M, Szydagis, M, Taylor, D, Thomson, J, Tripathi, M, Uvarov, S, Verbus, JR, Walsh, N, Webb, R, White, D, White, JT, Whitis, TJ, Wlasenko, M, Wolfs, FLH, Woods, M, and Zhang, C

Subjects

Nuclear and Plasma Physics, Particle and High Energy Physics, Physical Sciences, Dark matter detectors, Liquid xenon, physics.ins-det, hep-ex, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Nuclear & Particles Physics, Nuclear and plasma physics

Abstract

The Large Underground Xenon (LUX) collaboration has designed and constructed a dual-phase xenon detector, in order to conduct a search for Weakly Interacting Massive Particles (WIMPs), a leading dark matter candidate. The goal of the LUX detector is to clearly detect (or exclude) WIMPS with a spin independent cross-section per nucleon of 2×10-46cm2, equivalent to ∼1event/100kg/month in the inner 100-kg fiducial volume (FV) of the 370-kg detector. The overall background goals are set to have

Published

2013

27. An ultra-low background PMT for liquid xenon detectors

Author

Akerib, DS, Bai, X, Bernard, E, Bernstein, A, Bradley, A, Byram, D, Cahn, SB, Carmona-Benitez, MC, Carr, D, Chapman, JJ, Clark, K, Coffey, T, Edwards, B, de Viveiros, L, Dragowsky, M, Druszkiewicz, E, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Hall, C, Hanhardt, M, Holbrook, B, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Larsen, N, Lee, C, Lindote, A, Lopes, MI, Lyashenko, A, Malling, DC, Mannino, R, McKinsey, DN, Mei, D-M, Mock, J, Morii, M, Nelson, H, Neves, F, Nikkel, JA, Pangilinan, M, Phelps, P, Shutt, T, Silva, C, Skulski, W, Solovov, VN, Sorensen, P, Spaans, J, Stiegler, T, Sweany, M, Szydagis, M, Taylor, D, Thomson, J, Tripathi, M, Uvarov, S, Verbus, JR, Walsh, N, Webb, R, White, JT, Wlasenko, M, Wolfs, FLH, Woods, M, and Zhang, C

Subjects

PMT, Liquid xenon detectors, Radioactivity, physics.ins-det, astro-ph.IM, hep-ex, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences, Nuclear & Particles Physics

Abstract

Results are presented from radioactivity screening of two models of photomultiplier tubes designed for use in current and future liquid xenon experiments. The Hamamatsu 5.6 cm diameter R8778 PMT, used in the LUX dark matter experiment, has yielded a positive detection of four common radioactive isotopes: 238U, 232Th, 40K, and 60Co. Screening of LUX materials has rendered backgrounds from other detector materials subdominant to the R8778 contribution. A prototype Hamamatsu 7.6 cm diameter R11410 MOD PMT has also been screened, with benchmark isotope counts measured at

Published

2013

28. LUXSim: A component-centric approach to low-background simulations

Author

Akerib, DS, Bai, X, Bedikian, S, Bernard, E, Bernstein, A, Bradley, A, Cahn, SB, Carmona-Benitez, MC, Carr, D, Chapman, JJ, Clark, K, Classen, T, Coffey, T, Dazeley, S, De Viveiros, L, Dobi, A, Dragowsky, M, Druszkiewicz, E, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Hall, C, Hanhardt, M, Holbrook, B, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Lander, R, Larsen, N, Lee, C, Leonard, D, Lesko, K, Lyashenko, A, Malling, DC, Mannino, R, McKinsey, DN, Mei, DM, Mock, J, Morii, M, Nelson, H, Nikkel, JA, Pangilinan, M, Parker, PD, Phelps, P, Shutt, T, Skulski, W, Sorensen, P, Spaans, J, Stiegler, T, Svoboda, R, Sweany, M, Szydagis, M, Thomson, J, Tripathi, M, Verbus, JR, Walsh, N, Webb, R, White, JT, Wlasenko, M, Wolfs, FLH, Woods, M, and Zhang, C

Subjects

Simulation, Low-background, Dark matter, Underground, Geant4, physics.data-an, hep-ex, nucl-ex, Nuclear & Particles Physics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences

Abstract

Geant4 has been used throughout the nuclear and high-energy physics community to simulate energy depositions in various detectors and materials. These simulations have mostly been run with a source beam outside the detector. In the case of low-background physics, however, a primary concern is the effect on the detector from radioactivity inherent in the detector parts themselves. From this standpoint, there is no single source or beam, but rather a collection of sources with potentially complicated spatial extent. LUXSim is a simulation framework used by the LUX collaboration that takes a component-centric approach to event generation and recording. A new set of classes allows for multiple radioactive sources to be set within any number of components at run time, with the entire collection of sources handled within a single simulation run. Various levels of information can also be recorded from the individual components, with these record levels also being set at run time. This flexibility in both source generation and information recording is possible without the need to recompile, reducing the complexity of code management and the proliferation of versions. Within the code itself, casting geometry objects within this new set of classes rather than as the default Geant4 classes automatically extends this flexibility to every individual component. No additional work is required on the part of the developer, reducing development time and increasing confidence in the results. We describe the guiding principles behind LUXSim, detail some of its unique classes and methods, and give examples of usage. © 2012 Elsevier B.V. All rights reserved.

Published

2012

29. Data acquisition and readout system for the LUX dark matter experiment

Author

Akerib, DS, Bai, X, Bedikian, S, Bernard, E, Bernstein, A, Bradley, A, Cahn, SB, Carmona-Benitez, MC, Carr, D, Chapman, JJ, Clark, K, Classen, T, Coffey, T, Curioni, A, Dazeley, S, De Viveiros, L, Dragowsky, M, Druszkiewicz, E, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Hall, C, Hanhardt, M, Holbrook, B, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Lander, R, Larsen, N, Lee, C, Leonard, D, Lesko, K, Lyashenko, A, Malling, DC, Mannino, R, McKinsey, DN, Mei, D, Mock, J, Morii, M, Nelson, H, Nikkel, JA, Pangilinan, M, Phelps, P, Shutt, T, Skulski, W, Sorensen, P, Spaans, J, Stiegler, T, Svoboda, R, Sweany, M, Szydagis, M, Thomson, J, Tripathi, M, Verbus, JR, Walsh, N, Webb, R, White, JT, Wlasenko, M, Wolfs, FLH, Woods, M, and Zhang, C

Subjects

Dark matter detectors, Data acquisition, Liquid xenon, astro-ph.IM, Nuclear & Particles Physics, Astronomical and Space Sciences, Atomic, Molecular, Nuclear, Particle and Plasma Physics, Other Physical Sciences

Abstract

LUX is a two-phase (liquid/gas) xenon time projection chamber designed to detect nuclear recoils from interactions with dark matter particles. Signals from the LUX detector are processed by custom-built analog electronics which provide properly shaped signals for the trigger and data acquisition (DAQ) systems. The DAQ is composed of commercial digitizers with firmware customized for the LUX experiment. Data acquisition systems in rare-event searches must accommodate high rate and large dynamic range during precision calibrations involving radioactive sources, while also delivering low threshold for maximum sensitivity. The LUX DAQ meets these challenges using real-time baseline suppression that allows for a maximum event acquisition rate in excess of 1.5 kHz with virtually no deadtime. This paper describes the LUX DAQ and the novel acquisition techniques employed in the LUX experiment. © 2011 Elsevier B.V. All rights reserved.

Published

2012

30. Radio-assay of Titanium samples for the LUX Experiment

Author

Akerib, DS, Bai, X, Bedikian, S, Bernard, E, Bernstein, A, Bradley, A, Cahn, SB, Carmona-Benitez, MC, Carr, D, Chapman, JJ, Chan, Y-D, Clark, K, Classen, T, Coffey, T, Dazeley, S, deViveiros, L, Dragowsky, M, Druszkiewicz, E, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Hall, C, Hanhardt, M, Holbrook, B, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Lander, R, Larsen, N, Lee, C, Leonard, D, Lesko, K, Lyashenko, A, Malling, DC, Mannino, R, McKinsey, D, Mei, D, Mock, J, Morii, M, Nelson, H, Nikkel, JA, Pangilinan, M, Parker, PD, Phelps, P, Shutt, T, Skulski, W, Sorensen, P, Spaans, J, Stiegler, T, Svoboda, R, Smith, A, Sweany, M, Szydagis, M, Thomson, J, Tripathi, M, Verbus, JR, Walsh, N, Webb, R, White, JT, Wlasenko, M, Wolfs, FLH, Woods, M, Uvarov, S, and Zhang, C

Subjects

physics.ins-det, hep-ex

Abstract

We report on the screening of samples of titanium metal for theirradio-purity. The screening process described in this work led to the selectionof materials used in the construction of the cryostats for the LargeUnderground Xenon (LUX) dark matter experiment. Our measurements establishtitanium as a highly desirable material for low background experimentssearching for rare events. The sample with the lowest total long-lived activitywas measured to contain

Published

2011

31. After LUX: The LZ program

Author

Malling, DC, Chapman, JJ, Faham, CH, Fiorucci, S, Gaitskell, RJ, Pangilinan, M, Verbus, JR, Akerib, DS, Bradley, A, Carmona-Benitez, MC, Clark, K, Coffey, T, Dragowsky, M, Gibson, KR, Lee, C, Phelps, P, Shutt, T, Araújo, HM, Currie, A, Sumner, TJ, Bai, X, Hanhardt, M, Bedikian, S, Bernard, E, Cahn, SB, Kastens, L, Larsen, N, Lyashenko, A, McKinsey, DN, Nikkel, JA, Bernstein, A, Carr, D, Dazeley, S, Kazkaz, K, Sorensen, P, Classen, T, Holbrook, B, Lander, R, Mock, J, Svoboda, R, Sweany, M, Szydagis, M, Thomson, J, Tripathi, M, Walsh, N, Woods, M, de Viveiros, L, Lindote, A, Lopes, MI, Neves, F, Silva, C, Solovov, V, Druszkiewicz, E, Skulski, W, Wolfs, FLH, Hall, C, Leonard, D, Ihm, M, Jacobsen, RG, Lesko, K, Majewski, P, Mannino, R, Stiegler, T, Webb, R, White, JT, Mei, DM, Spaans, J, Zhang, C, Morii, M, Wlasenko, M, Murphy, ASJ, Reichhart, L, and Nelson, H

Subjects

astro-ph.IM, astro-ph.CO

Abstract

© Proceedings of the 2011 Meeting of the Division of Particles and Fields of the American Physical Society, DPF 2011. All rights reserved. The LZ program consists of two stages of direct dark matter searches using liquid Xe detectors. The first stage will be a 1.5-3 tonne detector, while the last stage will be a 20 tonne detector. Both devices will benefit tremendously from research and development performed for the LUX experiment, a 350 kg liquid Xe dark matter detector currently operating at the Sanford Underground Laboratory. In particular, the technology used for cryogenics and electrical feedthroughs, circulation and purification, low-background materials and shielding techniques, electronics, calibrations, and automated control and recovery systems are all directly scalable from LUX to the LZ detectors. Extensive searches for potential background sources have been performed, with an emphasis on previously undiscovered background sources that may have a significant impact on tonne-scale detectors. The LZ detectors will probe spin-independent interaction cross sections as low as 5 × 10-49 cm2 for 100 GeV WIMPs, which represents the ultimate limit for dark matter detection with liquid xenon technology.

Published

2011

32. Status of the LUX Dark Matter Search

Author

Fiorucci, S, Akerib, DS, Bedikian, S, Bernstein, A, Bolozdynya, A, Bradley, A, Carr, D, Chapman, J, Clark, K, Classen, T, Curioni, A, Dahl, E, Dazeley, S, de Viveiros, L, Druszkiewicz, E, Gaitskell, R, Hall, C, Hernandez Faham, C, Holbrook, B, Kastens, L, Kazkaz, K, Lander, R, Lesko, K, Malling, D, Mannino, R, McKinsey, D, Mei, D, Mock, J, Nikkel, J, Phelps, P, Schroeder, U, Shutt, T, Skulski, W, Sorensen, P, Spaans, J, Stiegler, T, Svoboda, R, Sweany, M, Thomson, J, Toke, J, Tripathi, M, Walsh, N, Webb, R, White, J, Wolfs, F, Woods, M, Zhang, C, Alverson, George, Nath, Pran, and Nelson, Brent

Subjects

Nuclear and Plasma Physics, Particle and High Energy Physics, Physical Sciences, Dark Matter, LUX, astro-ph.CO, astro-ph.IM

Abstract

The Large Underground Xenon (LUX) dark matter search experiment is currently being deployed at the Homestake Laboratory in South Dakota. We will highlight the main elements of design which make the experiment a very strong competitor in the field of direct detection, as well as an easily scalable concept. We will also present its potential reach for supersymmetric dark matter detection, within various timeframes ranging from 1 year to 5 years or more. © 2010 American Institute of Physics.

Published

2010

33. Status of the LUX dark matter search

Author

Fiorucci, S, Akerib, DS, Bedikian, S, Bernstein, A, Bolozdynya, A, Bradley, A, Carr, D, Chapman, J, Clark, K, Classen, T, Curioni, A, Dahl, E, Dazeley, S, De Viveiros, L, Druszkiewicz, E, Gaitskell, R, Hall, C, Hernandez Faham, C, Holbrook, B, Kastens, L, Kazkaz, K, Lander, R, Lesko, K, Malling, D, Mannino, R, McKinsey, D, Mei, D, Mock, J, Nikkel, J, Phelps, P, Schroeder, U, Shutt, T, Skulski, W, Sorensen, P, Spaans, J, Stiegler, T, Svoboda, R, Sweany, M, Thomson, J, Toke, J, Tripathi, M, Walsh, N, Webb, R, White, J, Wolfs, F, Woods, M, and Zhang, C

Subjects

Dark Matter, LUX, astro-ph.CO, astro-ph.IM

Abstract

The Large Underground Xenon (LUX) dark matter search experiment is currently being deployed at the Homestake Laboratory in South Dakota. We will highlight the main elements of design which make the experiment a very strong competitor in the field of direct detection, as well as an easily scalable concept. We will also present its potential reach for supersymmetric dark matter detection, within various timeframes ranging from 1 year to 5 years or more. © 2010 American Institute of Physics.

Published

2009

34. Design and expected performance of a fast neutron attenuation probe for light element density measurements

Author

Sweany, M. and Marleau, P.

Published

2016

35. A search for cosmogenic production of β-neutron emitting radionuclides in water

Author

Dazeley, S., Askins, M., Bergevin, M., Bernstein, A., Bowden, N.S., Shokair, T.M., Jaffke, P., Rountree, S.D., and Sweany, M.

Published

2016

36. Demonstration of two-dimensional time-encoded imaging of fast neutrons

Author

Brennan, J., Brubaker, E., Gerling, M., Marleau, P., McMillan, K., Nowack, A., Galloudec, N. Renard-Le, and Sweany, M.

Published

2015

37. Above-ground antineutrino detection for nuclear reactor monitoring

Author

Sweany, M., Brennan, J., Cabrera-Palmer, B., Kiff, S., Reyna, D., and Throckmorton, D.

Published

2015

38. Technical results from the surface run of the LUX dark matter experiment

Author

Akerib, D.S., Bai, X., Bernard, E., Bernstein, A., Bradley, A., Byram, D., Cahn, S.B., Carmona-Benitez, M.C., Chapman, J.J., Coffey, T., Dobi, A., Dragowsky, E., Druszkiewicz, E., Edwards, B., Faham, C.H., Fiorucci, S., Gaitskell, R.J., Gibson, K.R., Gilchriese, M., Hall, C., Hanhardt, M., Ihm, M., Jacobsen, R.G., Kastens, L., Kazkaz, K., Knoche, R., Larsen, N., Lee, C., Lesko, K.T., Lindote, A., Lopes, M.I., Lyashenko, A., Malling, D.C., Mannino, R., McKinsey, D.N., Mei, D., Mock, J., Moongweluwan, M., Morii, M., Nelson, H., Neves, F., Nikkel, J.A., Pangilinan, M., Pech, K., Phelps, P., Rodionov, A., Shutt, T., Silva, C., Skulski, W., Solovov, V.N., Sorensen, P., Stiegler, T., Sweany, M., Szydagis, M., Taylor, D., Tripathi, M., Uvarov, S., Verbus, J.R., de Viveiros, L., Walsh, N., Webb, R., White, J.T., Wlasenko, M., Wolfs, F.L.H., Woods, M., and Zhang, C.

Published

2013

39. LUX Cryogenics and Circulation

Author

Bradley, A.W., Akerib, D.S., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Cahn, S.B., Carmona-Benitez, M.C., Carr, D., Chapman, J.J., Clark, K., Classen, T., Coffey, T., Dazeley, S., de Viveiros, L., Dragowsky, M., Druszkiewicz, E., Faham, C.H., Fiorucci, S., Gaitskell, R.J., Gibson, K.R., Hall, C., Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R.G., Kastens, L., Kazkaz, K., Lander, R., Larsen, N., Lee, C., Lesko, K., Lindote, A., Lopes, M.I., Lyashenko, A., Malling, D.C., Mannino, R., McKinsey, D., Mei, D., Mock, J., Morii, M., Nelson, H., Neves, F., Nikkel, J.A., Pangilinan, M., Phelps, P., Cunha, J. Pinto da, Shutt, T., Silva, C., Skulski, W., Solovov, V.N., Sorensen, P., Spaans, J., Stiegler, T., Svoboda, R., Sweany, M., Szydagis, M., Thomson, J., Tripathi, M., Verbus, J.R., Walsh, N., Webb, R., White, J.T., Wlasenko, M., Wolfs, F.L.H., Woods, M., and Zhang, C.

Published

2012

40. Large-scale gadolinium-doped water Cherenkov detector for nonproliferation

Author

Sweany, M., Bernstein, A., Bowden, N.S., Dazeley, S., Keefer, G., Svoboda, R., and Tripathi, M.

Published

2011

41. Design and calibration of an optically segmented single volume scatter camera for neutron imaging

Author

Galindo-Tellez, A., primary, Keefe, K., additional, Adamek, E., additional, Brubaker, E., additional, Crow, B., additional, Dorrill, R., additional, Druetzler, A., additional, Felix, C.J., additional, Kaneshige, N., additional, Learned, J.G., additional, Manfredi, J.J., additional, Nishimura, K., additional, Pinto Souza, B., additional, Schoen, D., additional, and Sweany, M., additional

Published

2021

42. Current status of an optically-segmented single-volume scatter camera for neutron imaging

Author

Tellez-Galindo, A, Tellez-Galindo, A, Brown, JA, Brubaker, E, Cabrera-Palmer, B, Carlson, J, Dorrill, R, Druetzler, A, Elam, J, Febbraro, M, Feng, P, Folsom, M, Galino-Tellez, A, Goldblum, BL, Hausladen, P, Kaneshige, N, Keefe, K, Laplace, TA, Learned, JG, Mane, A, Manfredi, JJ, Marleau, P, Mattingly, J, Mishra, M, Moustafa, A, Nattress, J, Nishimura, K, Steele, J, Sweany, M, Weinfurther, K, Ziock, K, Tellez-Galindo, A, Tellez-Galindo, A, Brown, JA, Brubaker, E, Cabrera-Palmer, B, Carlson, J, Dorrill, R, Druetzler, A, Elam, J, Febbraro, M, Feng, P, Folsom, M, Galino-Tellez, A, Goldblum, BL, Hausladen, P, Kaneshige, N, Keefe, K, Laplace, TA, Learned, JG, Mane, A, Manfredi, JJ, Marleau, P, Mattingly, J, Mishra, M, Moustafa, A, Nattress, J, Nishimura, K, Steele, J, Sweany, M, Weinfurther, K, and Ziock, K

Abstract

The Single-Volume Scatter Camera (SVSC) approach to kinematic neutron imaging, in which an incident neutron’s direction is reconstructed via multiple neutron-proton scattering events, potentially offers much greater efficiency and portability than current systems. In our first design of an Optically-Segmented (OS) SVSC, the detector consists of an 8×8 array of 5×5×200 mm3 bars of EJ-204 scintillator wrapped in Teflon tape, optically coupled with SensL J-series 6 x 6 mm Silicon Photomultiplier (SiPM) arrays, all inside an aluminum frame that serves as a dark box. The SiPMs are read out using custom (multi-GSPS) waveform sampling electronics. In this work, construction, characterization, and electronics updates are reported. The position, time, and energy resolutions of individual bars were obtained by measuring different scintillators with different reflectors. This work was carried out in parallel at the University of Hawaii and at Sandia National Laboratories and resulted in the preliminary design of the camera. Monte-Carlo simulations using the Geant4 toolkit were carried out for individual scintillator bars, as well as the array setup. A custom analysis using ROOT libraries in C++ simulated the SiPM response from Geant4 photon hits. This analysis framework is under development and will allow for seamless comparisons between experimental and simulated data.

Published

2020

43. The single-volume scatter camera

Author

Manfredi, JJ, Fiederle, Michael1, Burger, Arnold, Payne, Stephen A, Manfredi, JJ, Adamek, E, Brown, JA, Brubaker, E, Cabrera-Palmer, B, Cates, J, Dorrill, R, Druetzler, A, Elam, J, Feng, PL, Folsom, M, Galindo-Tellez, A, Goldblum, BL, Hausladen, P, Kaneshige, N, Keefe, K, Laplace, TA, Learned, JG, Mane, A, Marleau, P, Mattingly, J, Mishra, M, Moustafa, A, Nattress, J, Nishimura, K, Steele, J, Sweany, M, Weinfurther, K, Ziock, KP, Manfredi, JJ, Fiederle, Michael1, Burger, Arnold, Payne, Stephen A, Manfredi, JJ, Adamek, E, Brown, JA, Brubaker, E, Cabrera-Palmer, B, Cates, J, Dorrill, R, Druetzler, A, Elam, J, Feng, PL, Folsom, M, Galindo-Tellez, A, Goldblum, BL, Hausladen, P, Kaneshige, N, Keefe, K, Laplace, TA, Learned, JG, Mane, A, Marleau, P, Mattingly, J, Mishra, M, Moustafa, A, Nattress, J, Nishimura, K, Steele, J, Sweany, M, Weinfurther, K, and Ziock, KP

Abstract

The multi-institution Single-Volume Scatter Camera (SVSC) collaboration led by Sandia National Laboratories (SNL) is developing a compact, high-efficiency double-scatter neutron imaging system. Kinematic emission imaging of fission-energy neutrons can be used to detect, locate, and spatially characterize special nuclear material. Neutron-scatter cameras, analogous to Compton imagers for gamma ray detection, have a wide field of view, good event-by-event angular resolution, and spectral sensitivity. Existing systems, however, suffer from large size and/or poor efficiency. We are developing high-efficiency scatter cameras with small form factors by detecting both neutron scatters in a compact active volume. This effort requires development and characterization of individual system components, namely fast organic scintillators, photodetectors, electronics, and reconstruction algorithms. In this presentation, we will focus on characterization measurements of several SVSC candidate scintillators. The SVSC collaboration is investigating two system concepts: the monolithic design in which isotropically emitted photons are detected on the sides of the volume, and the optically segmented design in which scintillation light is channeled along scintillator bars to segmented photodetector readout. For each of these approaches, we will describe the construction and performance of prototype systems. We will conclude by summarizing lessons learned, comparing and contrasting the two system designs, and outlining plans for the next iteration of prototype design and construction.

Published

2020

44. Radio-assay of Titanium samples for the LUX Experiment

Author

Akerib, D. S., Bai, X., Bedikian, S., Bernard, E., Bernstein, A., Bradley, A., Cahn, S. B., Carmona-Benitez, M. C., Carr, D., Chapman, J. J., Chan, Y-D, Clark, K., Classen, T., Coffey, T., Dazeley, S., Viveiros, L., Dragowsky, M., Druszkiewicz, E., Faham, C. H., Fiorucci, S., Gaitskell, R. J., Gibson, K. R., Carter Hall, Hanhardt, M., Holbrook, B., Ihm, M., Jacobsen, R. G., Kastens, L., Kazkaz, K., Lander, R., Larsen, N., Lee, C., Leonard, D., Lesko, K., Lyashenko, A., Malling, D. C., Mannino, R., Mckinsey, D., Mei, D., Mock, J., Morii, M., Nelson, H., Nikkel, J. A., Pangilinan, M., Parker, P. D., Phelps, P., Shutt, T., Skulski, W., Sorensen, P., Spaans, J., Stiegler, T., Svoboda, R., Smith, A., Sweany, M., Szydagis, M., Thomson, J., Tripathi, M., Verbus, J. R., Walsh, N., Webb, R., White, J. T., Wlasenko, M., Wolfs, F. L. H., Woods, M., Uvarov, S., and Zhang, C.

Subjects

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

Abstract

We report on the screening of samples of titanium metal for their radio-purity. The screening process described in this work led to the selection of materials used in the construction of the cryostats for the Large Underground Xenon (LUX) dark matter experiment. Our measurements establish titanium as a highly desirable material for low background experiments searching for rare events. The sample with the lowest total long-lived activity was measured to contain, The LUX Collaboration

Published

2018

45. After LUX: The LZ Program

Author

Malling, DC, Akerib, DS, Araujo, HM, Bai, X, Bedikian, S, Bernard, E, Bernstein, A, Bradley, A, Cahn, SB, Carmona-Benitez, MC, Carr, D, Chapman, JJ, Clark, K, Classen, T, Coffey, T, Curioni, A, Currie, A, Dazeley, S, Viveiros, LD, Dragowsky, M, Druszkiewicz, E, Faham, CH, Fiorucci, S, Gaitskell, RJ, Gibson, KR, Hall, C, Hanhardt, M, Holbrook, B, Ihm, M, Jacobsen, RG, Kastens, L, Kazkaz, K, Lander, R, Larsen, N, Lee, C, Leonard, D, Lesko, K, Lindote, A, Lopes, MI, Lyashenko, A, Majewski, P, Mannino, R, McKinsey, DN, Mei, D-M, Mock, J, Morii, M, Murphy, ASJ, Nelson, H, Neves, F, Nikkel, JA, Pangilinan, M, Phelps, P, Reichhart, L, Shutt, T, Silva, C, Skulski, W, Solovov, V, Sorensen, P, Spaans, J, Stiegler, T, Sumner, TJ, Svoboda, R, Sweany, M, Szydagis, M, Thomson, J, Tripathi, M, Verbus, JR, Walsh, N, Webb, R, White, JT, Wlasenko, M, Wolfs, FLH, Woods, M, and Zhang, C

Subjects

astro-ph.CO, astro-ph.IM

Abstract

The LZ program consists of two stages of direct dark matter searches using liquid Xe detectors. The first stage will be a 1.5-3 tonne detector, while the last stage will be a 20 tonne detector. Both devices will benefit tremendously from research and development performed for the LUX experiment, a 350 kg liquid Xe dark matter detector currently operating at the Sanford Underground Laboratory. In particular, the technology used for cryogenics and electrical feedthroughs, circulation and purification, low-background materials and shielding techniques, electronics, calibrations, and automated control and recovery systems are all directly scalable from LUX to the LZ detectors. Extensive searches for potential background sources have been performed, with an emphasis on previously undiscovered background sources that may have a significant impact on tonne-scale detectors. The LZ detectors will probe spin-independent interaction cross sections as low as 5E-49 cm2 for 100 GeV WIMPs, which represents the ultimate limit for dark matter detection with liquid xenon technology.

Published

2018

46. Interaction position, time, and energy resolution in organic scintillator bars with dual-ended readout

Author

Sweany, M., primary, Galindo-Tellez, A., additional, Brown, J., additional, Brubaker, E., additional, Dorrill, R., additional, Druetzler, A., additional, Kaneshige, N., additional, Learned, J., additional, Nishimura, K., additional, and Bae, W., additional

Published

2019

47. Program Manager's Questions for LL08-GdNdet-PD03 Development of Large Water-Based Neutron Detectors

Author

Dazeley, S, primary, Bernstein, A, additional, Sweany, M, additional, Ouedraogo, S, additional, and Svoboda, R, additional

Published

2009

48. The LUX prototype detector: Heat exchanger development

Author

Akerib, D.S., primary, Bai, X., additional, Bedikian, S., additional, Bernstein, A., additional, Bolozdynya, A., additional, Bradley, A., additional, Cahn, S.B., additional, Carr, D., additional, Chapman, J.J., additional, Clark, K., additional, Classen, T., additional, Curioni, A., additional, Dahl, C.E., additional, Dazeley, S., additional, de Viveiros, L., additional, Dragowsky, M., additional, Druszkiewicz, E., additional, Fiorucci, S., additional, Gaitskell, R.J., additional, Hall, C., additional, Faham, C., additional, Holbrook, B., additional, Kastens, L., additional, Kazkaz, K., additional, Kwong, J., additional, Lander, R., additional, Leonard, D., additional, Malling, D., additional, Mannino, R., additional, McKinsey, D.N., additional, Mei, D., additional, Mock, J., additional, Morii, M., additional, Nikkel, J.A., additional, Phelps, P., additional, Shutt, T., additional, Skulski, W., additional, Sorensen, P., additional, Spaans, J., additional, Steigler, T., additional, Svoboda, R., additional, Sweany, M., additional, Thomson, J., additional, Tripathi, M., additional, Walsh, N., additional, Webb, R., additional, White, J., additional, Wolfs, F.L.H., additional, Woods, M., additional, and Zhang, C., additional

Published

2013

49. The Large Underground Xenon (LUX) experiment

Author

Akerib, D.S., primary, Bai, X., additional, Bedikian, S., additional, Bernard, E., additional, Bernstein, A., additional, Bolozdynya, A., additional, Bradley, A., additional, Byram, D., additional, Cahn, S.B., additional, Camp, C., additional, Carmona-Benitez, M.C., additional, Carr, D., additional, Chapman, J.J., additional, Chiller, A., additional, Chiller, C., additional, Clark, K., additional, Classen, T., additional, Coffey, T., additional, Curioni, A., additional, Dahl, E., additional, Dazeley, S., additional, de Viveiros, L., additional, Dobi, A., additional, Dragowsky, E., additional, Druszkiewicz, E., additional, Edwards, B., additional, Faham, C.H., additional, Fiorucci, S., additional, Gaitskell, R.J., additional, Gibson, K.R., additional, Gilchriese, M., additional, Hall, C., additional, Hanhardt, M., additional, Holbrook, B., additional, Ihm, M., additional, Jacobsen, R.G., additional, Kastens, L., additional, Kazkaz, K., additional, Knoche, R., additional, Kyre, S., additional, Kwong, J., additional, Lander, R., additional, Larsen, N.A., additional, Lee, C., additional, Leonard, D.S., additional, Lesko, K.T., additional, Lindote, A., additional, Lopes, M.I., additional, Lyashenko, A., additional, Malling, D.C., additional, Mannino, R., additional, Marquez, Z., additional, McKinsey, D.N., additional, Mei, D.-M., additional, Mock, J., additional, Moongweluwan, M., additional, Morii, M., additional, Nelson, H., additional, Neves, F., additional, Nikkel, J.A., additional, Pangilinan, M., additional, Parker, P.D., additional, Pease, E.K., additional, Pech, K., additional, Phelps, P., additional, Rodionov, A., additional, Roberts, P., additional, Shei, A., additional, Shutt, T., additional, Silva, C., additional, Skulski, W., additional, Solovov, V.N., additional, Sofka, C.J., additional, Sorensen, P., additional, Spaans, J., additional, Stiegler, T., additional, Stolp, D., additional, Svoboda, R., additional, Sweany, M., additional, Szydagis, M., additional, Taylor, D., additional, Thomson, J., additional, Tripathi, M., additional, Uvarov, S., additional, Verbus, J.R., additional, Walsh, N., additional, Webb, R., additional, White, D., additional, White, J.T., additional, Whitis, T.J., additional, Wlasenko, M., additional, Wolfs, F.L.H., additional, Woods, M., additional, and Zhang, C., additional

Published

2013

50. An ultra-low background PMT for liquid xenon detectors

Author

Akerib, D.S., primary, Bai, X., additional, Bernard, E., additional, Bernstein, A., additional, Bradley, A., additional, Byram, D., additional, Cahn, S.B., additional, Carmona-Benitez, M.C., additional, Carr, D., additional, Chapman, J.J., additional, Clark, K., additional, Coffey, T., additional, Edwards, B., additional, de Viveiros, L., additional, Dragowsky, M., additional, Druszkiewicz, E., additional, Faham, C.H., additional, Fiorucci, S., additional, Gaitskell, R.J., additional, Gibson, K.R., additional, Hall, C., additional, Hanhardt, M., additional, Holbrook, B., additional, Ihm, M., additional, Jacobsen, R.G., additional, Kastens, L., additional, Kazkaz, K., additional, Larsen, N., additional, Lee, C., additional, Lindote, A., additional, Lopes, M.I., additional, Lyashenko, A., additional, Malling, D.C., additional, Mannino, R., additional, McKinsey, D.N., additional, Mei, D.-M, additional, Mock, J., additional, Morii, M., additional, Nelson, H., additional, Neves, F., additional, Nikkel, J.A., additional, Pangilinan, M., additional, Phelps, P., additional, Shutt, T., additional, Silva, C., additional, Skulski, W., additional, Solovov, V.N., additional, Sorensen, P., additional, Spaans, J., additional, Stiegler, T., additional, Sweany, M., additional, Szydagis, M., additional, Taylor, D., additional, Thomson, J., additional, Tripathi, M., additional, Uvarov, S., additional, Verbus, J.R., additional, Walsh, N., additional, Webb, R., additional, White, J.T., additional, Wlasenko, M., additional, Wolfs, F.L.H., additional, Woods, M., additional, and Zhang, C., additional

Published

2013