Dr. Kimberly Palladino

Low-energy (0.7-74 keV) nuclear recoil calibration of the LUX dark matter experiment using D-D neutron scattering kinematics

ArXiv 1608.05381 (2016)

Authors:

LUX Collaboration, DS Akerib, S Alsum, HM Araújo, X Bai, AJ Bailey, J Balajthy, P Beltrame, EP Bernard, A Bernstein, TP Biesiadzinski, EM Boulton, A Bradley, R Bramante, P Brás, D Byram, SB Cahn, MC Carmona-Benitez, C Chan, JJ Chapman, AA Chiller, C Chiller, A Currie, JE Cutter, TJR Davison, L de Viveiros, A Dobi, JEY Dobson, E Druszkiewicz, BN Edwards, CH Faham, S Fiorucci, RJ Gaitskell, VM Gehman, C Ghag, KR Gibson, MGD Gilchriese, CR Hall, M Hanhardt, SJ Haselschwardt, SA Hertel, DP Hogan, M Horn, DQ Huang, CM Ignarra, M Ihm, RG Jacobsen, W Ji, K Kamdin, K Kazkaz, D Khaitan, R Knoche, NA Larsen, C Lee, BG Lenardo, KT Lesko, A Lindote, MI Lopes, DC Malling, A Manalaysay, RL Mannino, MF Marzioni, DN McKinsey, DM Mei, J Mock, M Moongweluwan, JA Morad, A St J Murphy, C Nehrkorn, HN Nelson, F Neves, K O'Sullivan, KC Oliver-Mallory, KJ Palladino, M Pangilinan, EK Pease, P Phelps, L Reichhart, CA Rhyne, S Shaw, TA Shutt, C Silva, M Solmaz, VN Solovov, P Sorensen, S Stephenson, TJ Sumner, M Szydagis, DJ Taylor, WC Taylor, BP Tennyson, PA Terman, DR Tiedt, WH To, M Tripathi, L Tvrznikova, S Uvarov, JR Verbus, RC Webb, JT White, TJ Whitis, MS Witherell, FLH Wolfs, J Xu, K Yazdani, SK Young, C Zhang

Abstract:

The Large Underground Xenon (LUX) experiment is a dual-phase liquid xenon time projection chamber (TPC) operating at the Sanford Underground Research Facility in Lead, South Dakota. A calibration of nuclear recoils in liquid xenon was performed $\textit{in situ}$ in the LUX detector using a collimated beam of mono-energetic 2.45 MeV neutrons produced by a deuterium-deuterium (D-D) fusion source. The nuclear recoil energy from the first neutron scatter in the TPC was reconstructed using the measured scattering angle defined by double-scatter neutron events within the active xenon volume. We measured the absolute charge ($Q_{y}$) and light ($L_{y}$) yields at an average electric field of 180 V/cm for nuclear recoil energies spanning 0.7 to 74 keV and 1.1 to 74 keV, respectively. This calibration of the nuclear recoil signal yields will permit the further refinement of liquid xenon nuclear recoil signal models and, importantly for dark matter searches, clearly demonstrates measured ionization and scintillation signals in this medium at recoil energies down to $\mathcal{O}$(1 keV).

Characteristics of Four Upward-Pointing Cosmic-Ray-like Events Observed with ANITA.

Physical review letters 117:7 (2016) 071101

Authors:

PW Gorham, J Nam, A Romero-Wolf, S Hoover, P Allison, O Banerjee, JJ Beatty, K Belov, DZ Besson, WR Binns, V Bugaev, P Cao, C Chen, P Chen, JM Clem, A Connolly, B Dailey, C Deaconu, L Cremonesi, PF Dowkontt, MA DuVernois, RC Field, BD Fox, D Goldstein, J Gordon, C Hast, CL Hebert, B Hill, K Hughes, R Hupe, MH Israel, A Javaid, J Kowalski, J Lam, JG Learned, KM Liewer, TC Liu, JT Link, E Lusczek, S Matsuno, BC Mercurio, C Miki, P Miočinović, M Mottram, K Mulrey, CJ Naudet, J Ng, RJ Nichol, K Palladino, BF Rauch, K Reil, J Roberts, M Rosen, B Rotter, J Russell, L Ruckman, D Saltzberg, D Seckel, H Schoorlemmer, S Stafford, J Stockham, M Stockham, B Strutt, K Tatem, GS Varner, AG Vieregg, D Walz, SA Wissel, F Wu, ANITA Collaboration

Abstract:

We report on four radio-detected cosmic-ray (CR) or CR-like events observed with the Antarctic Impulsive Transient Antenna (ANITA), a NASA-sponsored long-duration balloon payload. Two of the four were previously identified as stratospheric CR air showers during the ANITA-I flight. A third stratospheric CR was detected during the ANITA-II flight. Here, we report on characteristics of these three unusual CR events, which develop nearly horizontally, 20-30 km above the surface of Earth. In addition, we report on a fourth steeply upward-pointing ANITA-I CR-like radio event which has characteristics consistent with a primary that emerged from the surface of the ice. This suggests a possible τ-lepton decay as the origin of this event, but such an interpretation would require significant suppression of the standard model τ-neutrino cross section.

FPGA-based trigger system for the LUX dark matter experiment

Nuclear Instruments and Methods in Physics Research Section A Accelerators Spectrometers Detectors and Associated Equipment Elsevier 818 (2016) 57-67

Authors:

DS Akerib, HM Araújo, X Bai, AJ Bailey, J Balajthy, P Beltrame, EP Bernard, A Bernstein, TP Biesiadzinski, EM Boulton, A Bradley, R Bramante, SB Cahn, MC Carmona-Benitez, C Chan, JJ Chapman, AA Chiller, C Chiller, A Currie, JE Cutter, TJR Davison, L de Viveiros, A Dobi, JEY Dobson, E Druszkiewicz, BN Edwards, CH Faham, S Fiorucci, RJ Gaitskell, VM Gehman, C Ghag, KR Gibson, MGD Gilchriese, CR Hall, M Hanhardt, SJ Haselschwardt, SA Hertel, DP Hogan, M Horn, DQ Huang, CM Ignarra, M Ihm, RG Jacobsen, W Ji, K Kazkaz, D Khaitan, R Knoche, NA Larsen, C Lee, BG Lenardo, KT Lesko, A Lindote, MI Lopes, DC Malling, AG Manalaysay, RL Mannino, MF Marzioni, DN McKinsey, D-M Mei, J Mock, M Moongweluwan, JA Morad, Murphy, C Nehrkorn, HN Nelson, F Neves, K O׳Sullivan, KC Oliver-Mallory, RA Ott, KJ Palladino, M Pangilinan, EK Pease, P Phelps, L Reichhart, C Rhyne, S Shaw, TA Shutt, C Silva, W Skulski, VN Solovov, P Sorensen, S Stephenson, TJ Sumner, M Szydagis, DJ Taylor, W Taylor, BP Tennyson, PA Terman, DR Tiedt, WH To, M Tripathi, L Tvrznikova, S Uvarov, JR Verbus, RC Webb, JT White, TJ Whitis, MS Witherell, FLH Wolfs, J Yin, SK Young, C Zhang

Tritium calibration of the LUX dark matter experiment

Physical Review D American Physical Society (APS) 93:7 (2016) 072009

Authors:

DS Akerib, HM Araújo, X Bai, AJ Bailey, J Balajthy, P Beltrame, EP Bernard, A Bernstein, TP Biesiadzinski, EM Boulton, A Bradley, R Bramante, SB Cahn, MC Carmona-Benitez, C Chan, JJ Chapman, AA Chiller, C Chiller, A Currie, JE Cutter, TJR Davison, L de Viveiros, A Dobi, JEY Dobson, E Druszkiewicz, BN Edwards, CH Faham, S Fiorucci, RJ Gaitskell, VM Gehman, C Ghag, KR Gibson, MGD Gilchriese, CR Hall, M Hanhardt, SJ Haselschwardt, SA Hertel, DP Hogan, M Horn, DQ Huang, CM Ignarra, M Ihm, RG Jacobsen, W Ji, K Kazkaz, D Khaitan, R Knoche, NA Larsen, C Lee, BG Lenardo, KT Lesko, A Lindote, MI Lopes, DC Malling, AG Manalaysay, RL Mannino, MF Marzioni, DN McKinsey, D-M Mei, J Mock, M Moongweluwan, JA Morad, A St. J. Murphy, C Nehrkorn, HN Nelson, F Neves, K O’Sullivan, KC Oliver-Mallory, RA Ott, KJ Palladino, M Pangilinan, EK Pease, P Phelps, L Reichhart, C Rhyne, S Shaw, TA Shutt, C Silva, VN Solovov, P Sorensen, S Stephenson, TJ Sumner, M Szydagis, DJ Taylor, W Taylor, BP Tennyson, PA Terman, DR Tiedt, WH To, M Tripathi, L Tvrznikova, S Uvarov, JR Verbus, RC Webb, JT White, TJ Whitis, MS Witherell, FLH Wolfs, SK Young, C Zhang

DEAP-3600 Dark Matter Search

Nuclear and Particle Physics Proceedings Elsevier 273 (2016) 340-346

Authors:

M Kuźniak, DEAP Collaboration, P-A Amaudruz, M Batygov, B Beltran, J Bonatt, MG Boulay, B Broerman, JF Bueno, A Butcher, B Cai, M Chen, R Chouinard, BT Cleveland, K Dering, J DiGioseffo, F Duncan, T Flower, R Ford, P Giampa, P Gorel, K Graham, DR Grant, E Guliyev, AL Hallin, M Hamstra, P Harvey, CJ Jillings, I Lawson, O Li, P Liimatainen, P Majewski, AB McDonald, T McElroy, K McFarlane, J Monroe, A Muir, C Nantais, C Ng, AJ Noble, C Ouellet, K Palladino, P Pasuthip, SJM Peeters, T Pollmann, W Rau, F Retière, N Seeburn, K Singhrao, P Skensved, B Smith, T Sonley, J Tang, E Vázquez-Jáuregui, L Veloce, J Walding, M Ward