NSR Query Results
Output year order : Descending NSR database version of April 26, 2024. Search: Author = D.N.McKinsey Found 13 matches. 2023BE19 Phys.Rev. C 108, 045503 (2023) E.P.Bernard, E.Mizrachi, J.Kingston, J.Xu, S.V.Pereverzev, T.Pershing, R.Smith, C.G.Prior, N.S.Bowden, A.Bernstein, C.R.Hall, E.Pantic, M.Tripathi, D.N.McKinsey, P.S.Barbeau Thermodynamic stability of xenon-doped liquid argon detectors
doi: 10.1103/PhysRevC.108.045503
2021AK04 Phys.Rev. C 104, 065501 (2021) D.S.Akerib, A.K.Al Musalhi, S.K.Alsum, C.S.Amarasinghe, A.Ames, T.J.Anderson, N.Angelides, H.M.Araujo, J.E.Armstrong, M.Arthurs, X.Bai, J.Balajthy, S.Balashov, J.Bang, J.W.Bargemann, D.Bauer, A.Baxter, P.Beltrame, E.P.Bernard, A.Bernstein, A.Bhatti, A.Biekert, T.P.Biesiadzinski, H.J.Birch, G.M.Blockinger, E.Bodnia, B.Boxer, C.A.J.Brew, P.Bras, S.Burdin, J.K.Busenitz, M.Buuck, R.Cabrita, M.C.Carmona-Benitez, M.Cascella, C.Chan, N.I.Chott, A.Cole, M.V.Converse, A.Cottle, G.Cox, O.Creaner, J.E.Cutter, C.E.Dahl, L.de Viveiros, J.E.Y.Dobson, E.Druszkiewicz, S.R.Eriksen, A.Fan, S.Fayer, N.M.Fearon, S.Fiorucci, H.Flaecher, E.D.Fraser, T.Fruth, R.J.Gaitskell, J.Genovesi, C.Ghag, E.Gibson, S.Gokhale, M.G.D.van der Grinten, C.B.Gwilliam, C.R.Hall, S.J.Haselschwardt, S.A.Hertel, M.Horn, D.Q.Huang, M.C.I.gnarra, O.Jahangir, R.S.James, W.Ji, J.Johnson, A.C.Kaboth, A.C.Kamaha, K.Kamdin, K.Kazkaz, D.Khaitan, A.Khazov, I.Khurana, D.Kodroff, L.Korley, E.V.Korolkova, H.Kraus, S.Kravitz, L.Kreczko, B.Krikler, V.A.Kudryavtsev, E.A.Leason, J.Lee, D.S.Leonard, K.T.Lesko, C.Levy, J.Liao, J.Lin, A.Lindote, R.Linehan, W.H.Lippincott, X.Liu, M.I.Lopes, E.Lopez Asamar, B.Lopez Paredes, W.Lorenzon, S.Luitz, P.A.Majewski, A.Manalaysay, L.Manenti, R.L.Mannino, N.Marangou, M.E.McCarthy, D.N.McKinsey, J.McLaughlin, E.H.Miller, E.Mizrachi, A.Monte, M.E.Monzani, J.A.Morad, J.D.Morales Mendoza, E.Morrison, B.J.Mount, A.St.J.Murphy, D.Naim, A.Naylor, C.Nedlik, H.N.Nelson, F.Neves, J.A.Nikoleyczik, A.Nilima, I.Olcina, K.C.Oliver-Mallory, S.Pal, K.J.Palladino, J.Palmer, S.Patton, N.Parveen, E.K.Pease, B.Penning, G.Pereira, A.Piepke, Y.Qie, J.Reichenbacher, C.A.Rhyne, A.Richards, Q.Riffard, G.R.C.Rischbieter, R.Rosero, P.Rossiter, D.Santone, A.B.M.R.Sazzad, R.W.Schnee, P.R.Scovell, S.Shaw, T.A.Shutt, J.J.Silk, C.Silva, R.Smith, M.Solmaz, V.N.Solovov, P.Sorensen, J.Soria, I.Stancu, A.Stevens, K.Stifter, B.Suerfu, T.J.Sumner, N.Swanson, M.Szydagis, W.C.Taylor, R.Taylor, D.J.Temples, P.A.Terman, D.R.Tiedt, M.Timalsina, W.H.To, D.R.Tovey, M.Tripathi, D.R.Tronstad, W.Turner, U.Utku, A.Vaitkus, B.Wang, J.J.Wang, W.Wang, J.R.Watson, R.C.Webb, R.G.White, T.J.Whitis, M.Williams, F.L.H.Wolfs, D.Woodward, C.J.Wright, X.Xiang, J.Xu, M.Yeh, P.Zarzhitsky Projected sensitivity of the LUX-ZEPLIN experiment to the two-neutrino and neutrinoless double β decays of 134Xe RADIOACTIVITY 134Xe(2β-); measured recoiling nuclei and electrons, decay energy spectra using LUX-ZEPLIN (LZ) detector of liquid xenon (LXe), with scintillation and electro-luminescence light detected using 494 photomultipliers at Sanford Underground Research Facility (SURF) in South Dakota; deduced lower limits of T1/2 values for 2νββ and 0νββ decay modes.
doi: 10.1103/PhysRevC.104.065501
2021AV04 Phys.Rev. D 104, 112007 (2021) A.Avasthi, T.W.Bowyer, C.Bray, T.Brunner, N.Catarineu, E.Church, R.Guenette, S.J.Haselschwardt, J.C.Hayes, M.Heffner, S.A.Hertel, P.H.Humble, A.Jamil, S.H.Kim, R.F.Lang, K.G.Leach, B.G.Lenardo, W.H.Lippincott, A.Marino, D.N.McKinsey, E.H.Miller, D.C.Moore, B.Mong, B.Monreal, M.E.Monzani, I.Olcina, J.L.Orrell, S.Pang, A.Pocar, P.C.Rowson, R.Saldanha, S.Sangiorgio, C.Stanford, A.Visser Kiloton-scale xenon detectors for neutrinoless double beta decay and other new physics searches RADIOACTIVITY 134,136Xe(2β-); analyzed available data; deduced neutrinoless mode T1/2 limits.
doi: 10.1103/PhysRevD.104.112007
2016AM03 Astropart.Phys. 85, 1 (2016) P.-A.Amaudruz, M.Batygov, B.Beltran, J.Bonatt, K.Boudjemline, M.G.Boulay, B.Broerman, J.F.Bueno, A.Butcher, B.Cai, T.Caldwell, M.Chen, R.Chouinard, B.T.Cleveland, D.Cranshaw, K.Dering, F.Duncan, N.Fatemighomi, R.Ford, R.Gagnon, P.Giampa, F.Giuliani, M.Gold, V.V.Golovko, P.Gorel, E.Grace, K.Graham, D.R.Grant, R.Hakobyan, A.L.Hallin, M.Hamstra, P.Harvey, C.Hearns, J.Hofgartner, C.J.Jillings, M.Kuzniak, I.Lawson, F.La Zia, O.Li, J.J.Lidgard, P.Liimatainen, W.H.Lippincott, R.Mathew, A.B.McDonald, T.McElroy, K.McFarlane, D.N.McKinsey, R.Mihdiyev, J.Monroe, A.Muir, C.Nantais, K.Nicolics, J.Nikkel, A.J.Noble, E.O'Dwyer, K.Olsen, C.Ouellet, P.Pasuthip, S.J.M.Peeters, T.Pollmann, W.Rau, F.Retiere, M.Ronquest, N.Seeburn, P.Skensved, B.Smith T.Sonley, J.Tang, E.Vazquez-Jauregui, L.Veloce, J.Walding, M.Ward, K.Olsen, C.Ouellet, P.Pasuthip, S.J.M.Peeters, T.Pollmann, W.Rau, F.Retiere, M.Ronquest, N.Seeburn, P.Skensved, B.Smith, T.Sonley, J.Tang, E.Vazquez-Jauregui, L.Veloce, J.Walding, M.Ward Measurement of the scintillation time spectra and pulse-shape discrimination of low-energy β and nuclear recoils in liquid argon with DEAP-1 NUCLEAR REACTIONS Ar(n, n), E<100 keV; measured nuclear recoils, Eβ, Iβ; deduced pulse-shape discrimination of recoils. Implications for dark matter sensitivities.
doi: 10.1016/j.astropartphys.2016.09.002
2012GA25 Phys.Rev. C 85, 065811 (2012) D.Gastler, E.Kearns, A.Hime, L.C.Stonehill, S.Seibert, J.Klein, W.H.Lippincott, D.N.McKinsey, J.A.Nikkel Measurement of scintillation efficiency for nuclear recoils in liquid argon NUCLEAR REACTIONS Ar(n, n'), E=2.8 MeV; measured recoil energy spectra, σ(θ); deduced scintillation efficiency. Monte Carlo simulations.
doi: 10.1103/PhysRevC.85.065811
2012LI34 Phys.Rev. C 86, 015807 (2012) W.H.Lippincott, K.J.Coakley, D.Gastler, E.Kearns, D.N.McKinsey, J.A.Nikkel Scintillation yield and time dependence from electronic and nuclear recoils in liquid neon
doi: 10.1103/PhysRevC.86.015807
2010LI13 Phys.Rev. C 81, 045803 (2010) W.H.Lippincott, S.B.Cahn, D.Gastler, L.W.Kastens, E.Kearns, D.N.McKinsey, J.A.Nikkel Calibration of liquid argon and neon detectors with 83Krm RADIOACTIVITY 83mKr(IT)[from 83Rb(ϵ)]; measured Eγ, Iγ, half-life in liquid argon and neon environments. Discussed applicability of 83mKr as a calibration source for liquid argon, neon dark matter and solar neutrino detectors.
doi: 10.1103/PhysRevC.81.045803
2010MA13 Phys.Rev. C 81, 025808 (2010) A.Manzur, A.Curioni, L.Kastens, D.N.McKinsey, K.Ni, T.Wongjirad Scintillation efficiency and ionization yield of liquid xenon for monoenergetic nuclear recoils down to 4 keV NUCLEAR REACTIONS Xe(n, X), E=2.8 MeV; measured γ spectra; deduced relative scintillation efficiency of liquid Xe scintillation detector for nuclear recoils of energies between 4 and 66 keV; Monte Carlo simulations. Implications for limits of detection of dark matter as weakly-interacting massive particles (WIMPs).
doi: 10.1103/PhysRevC.81.025808
2009KA30 Phys.Rev. C 80, 045809 (2009) L.W.Kastens, S.B.Cahn, A.Manzur, D.N.McKinsey Calibration of a liquid xenon detector with 83Krm RADIOACTIVITY 83mKr(IT)[from 83Rb(EC)]; measured Eγ, conversion electrons, (ce)(ce)(t), and level half-life using liquid xenon scintillation detector. Calibration of liquid xenon detector. Relevance to classical turbulence in liquid or gaseous helium.
doi: 10.1103/PhysRevC.80.045809
2008LI40 Phys.Rev. C 78, 035801 (2008); Errata Phys.Rev. C 81, 039901 (2010) W.H.Lippincott, K.J.Coakley, D.Gastler, A.Hime, E.Kearns, D.N.McKinsey, J.A.Nikkel, L.C.Stonehill Scintillation time dependence and pulse shape discrimination in liquid argon
doi: 10.1103/PhysRevC.78.035801
2005AP05 Phys.Rev. D 72, 072006 (2005) E.Aprile, K.L.Giboni, P.Majewski, K.Ni, M.Yamashita, R.Hasty, A.Manzur, D.N.McKinsey Scintillation response of liquid xenon to low energy nuclear recoils NUCLEAR REACTIONS Xe(n, n), E=2.4 MeV; measured scintillation response to nuclear recoil.
doi: 10.1103/PhysRevD.72.072006
2004SC01 Nucl.Instrum.Methods Phys.Res. B215, 531 (2004) M.H.Schleier-Smith, L.D.van Buuren, J.M.Doyle, S.N.Dzhosyuk, D.M.Gilliam, C.E.H.Mattoni, D.N.McKinsey, L.Yang, P.R.Huffman The production of nitrogen-13 by neutron capture in boron compounds NUCLEAR REACTIONS 10B(α, n), E ≈ 1.47 MeV; measured production rate in several compounds. Activation technique, α particles from thermal neutron irradiation.
doi: 10.1016/j.nimb.2003.09.022
2001BR15 Phys.Rev. C63, 055502 (2001) C.R.Brome, J.S.Butterworth, S.N.Dzhosyuk, C.E.H.Mattoni, D.N.McKinsey, J.M.Doyle, P.R.Huffman, M.S.Dewey, F.E.Wietfeldt, R.Golub, K.Habicht, G.L.Greene, S.K.Lamoreaux, K.J.Coakley Magnetic Trapping of Ultracold Neutrons RADIOACTIVITY 1n(β-); measured trapped neutron population vs time; deduced T1/2. Magnetic confinement of ultracold neutrons.
doi: 10.1103/PhysRevC.63.055502
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