DOCSLIB.ORG

Book of Abstracts Ii Contents

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Book of Abstracts Ii Contents IDM 2018 Sunday, 22 July 2018 - Friday, 27 July 2018 MacMillian Book of Abstracts ii Contents Probing Velocity Dependent Self Intereacting Dark Matter with Neutrino Telescopes. 1 Doping LXe TPCs with helium for light dark matter ..................... 1 Long-lived particles at the LHC: catching them in time ................... 1 Recent PandaX-II Results on Dark Matter Search and PandaX-4T Upgrade Status . 2 XENONnT - The next step in XENON Dark Matter Search ................. 2 Projected WIMP sensitivity of the LUX-ZEPLIN dark matter experiment . 2 The Impact of antiproton and antimatter nuclei measurements on dark matter searches . 3 Dark matter annual modulation with SABRE ......................... 3 Cosmological signatures of decaying dark matter ...................... 4 Looking for ultra light axion-like particles in the CMB ................... 4 (Now combined) Dark matter search with a light mediator at PandaX-II experiment . 4 SnowBall Chamber: Supercooled Water for Low-Mass Dark Matter ............ 5 The future PICO programme .................................. 5 DARWIN – The Ultimate WIMP Detector ........................... 6 Astrophysical Signatures of Dark Matter Accumulation in Neutron Stars . 6 Multiwavelength analysis of annihilating dark matter as the origin of the gamma-ray emis- sion from M31 ........................................ 7 Exposing Dark Sector with Future Z-Factories ........................ 7 Sexaquark and other uds-quark Dark Matter ......................... 7 First Results from the ADMX-G2 Axion Search ........................ 8 Recent results from the COSINE-100 experiment ....................... 8 Direct search for light dark matter with the CRESST-III experiment ............ 9 COSINUS: Probing the DAMA/LIBRA claim with NaI-based cryogenic detectors . 9 Review on directional direct dark matter search with gaseous detectors .......... 9 iii NEWAGE ............................................ 10 Directional Search for Dark Matter Using Nuclear Emulsion . 10 MADMAX: A new way to search for QCD Axion Dark Matter with a Dielectric Haloscope 11 Modelling of electromagnetic backgrounds in the CRESST experiment . 11 One year of XENON1T ..................................... 11 Directional Dark Matter search with optical readouts and the CYGNO project . 12 (Poster) Results from the CRESST-III experiment ....................... 12 Status of the LZ dark matter search .............................. 13 GAPS: Cosmic-ray antinuclei for dark matter searches ................... 13 Electron Recoil Bubble Nucleation in PICO Bubble Chambers . 13 First results of high voltage breakdown studies with XeBrA . 14 (Withdrawn) Concentrated Dark Matter and Primordial Black Holes . 14 Atomic Aspects of Light Dark Matter Searches ........................ 15 The Cosmic Axion Spin Precession Experiment ....................... 15 The Status of Interpretations of the Galactic Center Excess . 15 A Particle Physicist’s Perspective on the EDGES Anomaly . 16 Updated Dark Matter Search Results from the PICO-60 Bubble Chamber . 16 DANAE – A new attempt to search for Dark Matter with DEPFET-RNDR detectors . 16 (Duplicate) Astrophysical Signatures of Dark Matter Accumulation in Neutron Stars . 17 21-cm Implications for Dark Matter: Results ......................... 17 Complete CMB Constraints for Millicharged Dark Matter . 18 A combined energy scale for WIMP searches in liquid argon with the DarkSide-50 detector ................................................ 18 Aspects of Dark Matter Axion Clumps ............................ 19 The Stochastic Axion Scenario ................................. 19 Simulations for the LUX-ZEPLIN Experiment ........................ 19 Searching for Dark Matter at the Cosmic Dawn ....................... 20 The COHERENT collaboration and its first observation ofCEνNS . 20 Capture and decay of electroweak WIMPonium ....................... 21 NEWS-G Light dark matter searches with a Spherical Proportional Counter . 21 iv Dwarf galaxies J-factors without priors: a frequentist Jeans analysis consistent with indi- rect Dark Matter searches ................................. 21 Future prospects for axion haloscopes: Multiple cavities and really strong magnets . 22 (Withdrawn) Underground Laboratory of Modane (LSM) ; Multi- disciplinarily and Rare events experiments cozy host ............................... 22 Direct dark matter search with CDEX at CJPL ........................ 23 Material Informatics for Dark Matter Detection ....................... 23 The Spin-independent analysis of one tonne-year of XENON1T data . 24 Testing DAMA/LIBRA result with ANAIS-112 experiment at the Canfranc Underground Laboratory .......................................... 24 Status of the TREX-DM experiment at the Canfranc Underground Laboratory . 24 Detector Stability of COSINE-100 ............................... 25 First Evidence for Radon Daughter Solubility in Liquid Xenon . 25 Two Distinct Components of the Delayed Single Electron Noise in Liquid Xenon Emission Detectors ........................................... 26 Rare-event searches using the Majorana Demonstrator ................... 26 Background Assessment of the COSINE-100 Experiment . 27 Sub-GeV Dark Matter Results from a Single Electron-Hole-Pair SuperCDMS Detector . 27 Phase 2 Upgrades for the HAYSTAC Axion Experiment ................... 28 The PTOLEMY-G experiment for light dark matter direct detection . 28 Dark decay of the neutron ................................... 28 Background analysis in a one tonne-year dark matter search of XENON1T . 29 Recent Analysis Efforts of the LUX Collaboration ...................... 29 Dark Photon Searches with SuperCDMS Technology .................... 29 Understanding eV-threshold calorimeters for SuperCDMS . 30 Low-mass WIMP searches with EDELWEISS ......................... 30 SuperCDMS Detector Performance and Early Science from CUTE . 30 Early- and Late-Time Scattering of Dark Matter and Baryons in Cosmology . 31 Status of the DEAP-3600 dark matter search ......................... 31 Production and high voltage testing of the LZ detector grids . 32 Results on sub-GeV dark matter direct detection with LUX Run 3 data by using Bremsstrahlung and Migdal-effect signal .................................. 32 v Effects of Dark Matter Distribution Uncertainties on Milky Way Satellite Galaxy DarkMat- ter Searches ......................................... 32 Potassium and Dark Matter: the KDK Experiment ...................... 33 Point Sources at the Galactic Center .............................. 33 Neutron production in radioactive processes relevant to underground experiments . 33 ER/NR Discrimination in Liquid Xenon with the LUX Experiment . 34 HeRALD: direct detection with superfluid 4He ........................ 34 Measurement of Background Gamma Flux in the Davis Cavern for the LZ Experiment . 34 (Withdrawn) Select Effective Field Theory Results from the 2014-2016 LUX WIMP search run .............................................. 35 21-cm Implications for Dark Matter: Introduction ...................... 35 The Noble Element Simulation Technique (NEST) Version 2.0 . 36 A category of extremely-fast events (EFEs) in pPCGe detectors used in CDEX . 36 Search for low mass dark matter at DUNE .......................... 36 Development of Cryogenic Thermal Detectors for Sub-GeV Dark Matter . 37 GeV-Scale Thermal WIMPs: Not Even Slightly Dead ..................... 37 Dark Matter Model or Mass: Benchmark-Free Forecasting for Future Detectors . 38 Status and Projected Sensitivity for SuperCDMS SNOLAB . 38 A Search for Axion Dark Matter with the HAYSTAC Experiment . 39 Measurements of electron extraction efficiency and low-energy electron recoil response in a two-phase xenon time projection chamber ....................... 39 Generalised dark matter and diminishing the low CMB multipole tension . 39 Early dark energy and the Hubble tension .......................... 40 Status and plans for the DAMIC experiment at SNOLAB and Modane . 40 Searching for Decaying Particles with Line Intensity Mapping . 41 Dark Matter Axion Condensates: Stability and Astrophysical Properties . 41 Cosmological adiabatic conversion between QCD axion and ALP . 42 Dark matter and WIMPy baryogenesis in Scotogenic Model . 42 Paleo Detectors of Dark Matter ................................ 43 Welcome to IDM and Brown University ............................ 43 Complementarity for Dark Sector Bound States ....................... 43 vi Non-relativistic effective field theory of scalar field and longevity of condensates . 44 Duration of classicality of the axion dark matter condensate . 44 Estimating the local dark matter content using Gaia DR2 . 44 Lines, Boxes, and Energy Duality: Deciphering Astrophysical and Cosmological Imprints of Extended Dark Sectors .................................. 45 Reaching Beyond the Standard Scenarios: From Strongly Coupled Dark Sectors and Ther- mal Freezeout to Cosmological Phase Transitions and the Lifetime Frontier . 45 Nigel Smith (Executive Director, SNOLAB): Development of Deep Underground Facilities 46 CYGNUS - a multi-latitude directional WIMP experiment . 46 Low background Counting Facilities at SNOLAB: Current and Future . 46 Searches for Dark Matter Mediators at CMS ......................... 47 Astrophysical vs. dark matter interpretations of gamma-ray observations in dwarf galaxies ................................................ 47 Dark Matter-Baryon Scattering in Global 21cm Signal .................... 48 Reception Drinks + Registration
Load more

Recommended publications
  • A Statistical Framework for the Characterisation of WIMP Dark Matter with the LUX-ZEPLIN Experiment
    A statistical framework for the characterisation of WIMP dark matter with the LUX-ZEPLIN experiment Ibles Olcina Samblas Department of Physics A thesis submitted for the degree of Doctor of Philosophy November 2019 Abstract Several pieces of astrophysical evidence, from galactic to cosmological scales, indicate that most of the mass in the universe is composed of an invisible and essentially collisionless substance known as dark matter. A leading particle candidate that could provide the role of dark matter is the Weakly Interacting Massive Particle (WIMP), which can be searched for directly on Earth via its scattering off atomic nuclei. The LUX-ZEPLIN (LZ) experiment, currently under construction, employs a multi-tonne dual-phase xenon time projection chamber to search for WIMPs in the low background environment of the Davis Campus at the Sanford Underground Research Facility (South Dakota, USA). LZ will probe WIMP interactions with unprecedented sensitivity, starting to explore regions of the WIMP parameter space where new backgrounds are expected to arise from the elastic scattering of neutrinos off xenon nuclei. In this work the theoretical and computational framework underlying the calculation of the sensitivity of the LZ experiment to WIMP-nucleus scattering interactions is presented. After its planned 1000 live days of exposure, LZ will be able to achieve a 3σ discovery for spin independent cross sections above 3.0 10 48 cm2 at 40 GeV/c2 WIMP mass or exclude at × − 90% CL a cross section of 1.3 10 48 cm2 in the absence of signal. The sensitivity of LZ × − to spin-dependent WIMP-neutron and WIMP-proton interactions is also presented.
    [Show full text]
  • Book of Abstracts Ii Contents
    DMSS: A Dark Matter Summer School Monday, 16 July 2018 - Friday, 20 July 2018 Other Institute Book of Abstracts ii Contents Introduction to Dark Matter .................................. 1 Supersymmetry ......................................... 1 Large Scale Structure Formation ................................ 1 Roundtable Discussions ..................................... 1 Dark Matter in the Milky Way ................................. 1 Neutrinos ............................................ 1 Direct Detection of Dark Matter ................................ 1 Roundtable Discussions ..................................... 1 Indirect Dark Matter Searches ................................. 2 Statistical Methods used in Dark Matter ............................ 2 Axions .............................................. 2 Cosmic Microwave Background ................................ 2 Non-SUSY Dark Matter ..................................... 2 Roundtable Discussions ..................................... 2 Dark Matter at the LHC ..................................... 2 Dark Energy ........................................... 2 Roundtable Discussions ..................................... 3 Roundtable Discussions ..................................... 3 Dark Matter search activity at the University of Montreal .................. 3 Extra Dimensions in High-Mass Diphoton Spectrum at 13 TeV ............... 3 The XENONnT Time Projection Chamber .......................... 4 Calibration of the XENON1T experiment at low energies using a Kr83m source . 4 Gravitational-wave
    [Show full text]
  • LUX Detector
    LUX results and LZ sensitivity to dark matter WIMPs Vitaly A. Kudryavtsev University of Sheffield for the LUX and LZ Collaborations Outline n Dark matter direct detection with two-phase noble element instruments. n LUX detector. n LUX results: o WIMPs – spin-independent interactions; o WIMPs – spin-dependent interactions; o Axions and axion-like particles (ALPs). o Modulation search. n LZ detector. n Backgrounds n Sensitivity to WIMPs. n Conclusions. ICNFP2018, 6 July 2018 Vitaly Kudryavtsev 2 Principle of WIMP detection in LXe TPC n Liquid xenon time projection chamber – LXe TPC. n S1 – primary scintillation. n S2 –secondary scintillation, proportional to ionisation. n Position reconstruction based on the light pattern in the PMTs and delay between S2 and S1. ICNFP2018, 6 July 2018 Vitaly Kudryavtsev 3 Advantages of LXe n Good scintillator. n Two-phase -> TPC with good position resolution. n Self-shielding. n Good discrimination between electron recoils (ERs) and nuclear recoils (NRs). n High atomic mass: spin-independent cross- section ∝ A2 n Presence of even-odd isotopes (odd number of neutrons) for spin-dependent studies. n Other physics: o Axion search, o Neutrinoless double-beta decay. LZ Collaboration, LZ TDR, 1703.09144v1 [physics.ins-det] ICNFP2018, 6 July 2018 Vitaly Kudryavtsev 4 LUX Collaboration ² Brown University ² University at Albany, SUNY ² Imperial College London ² University College London ² LIP Coimbra, Portugal ² University of California, Berkeley ² Lawrence Berkley National Laboratory ² University of California, Davis
    [Show full text]
  • Dark Matter Vienna University of Technology V2.1
    Dark Matter Vienna University of Technology V2.1 Jochen Schieck and Holger Kluck Institut f¨urHochenergiephysik Nikolsdorfer Gasse 18 1050 Wien Atominstitut derTechnischen Universit¨atWien Stadionallee 2 1020 Wien Wintersemester 2017/18 18.12.2017 2 Contents 1 Introduction 7 1.1 What is "Dark Matter" . .7 1.1.1 Dark . .7 1.1.2 Matter . .7 1.1.3 Cosmology . .7 1.1.4 Massive particles as origin of "Dark Matter" . .7 1.1.5 "Dark Matter" as contribution to the energy density of the universe in Cosmology . .7 1.2 First Indication of observing "Dark Matter" . 13 1.3 Brief Introduction to Cosmology . 15 1.3.1 Special Relativity . 16 1.3.2 Differential geometry . 16 1.3.3 General Relativity . 16 1.3.4 Cosmology . 17 1.3.5 Decoupling of matter and radiation . 18 1.4 The Standard Model of Particle Physics . 19 1.4.1 The matter content of the Standard Model . 19 1.4.2 Forces within the Standard Model . 19 1.4.3 Shortcoming of the Standard Model . 20 1.4.4 Microscopic Behaviour of Gravity . 21 2 Evidence 23 2.1 Dynamics of Galaxies . 23 2.2 Gravitational Lensing . 24 2.2.1 Bullet Cluster . 31 2.3 Cosmic Microwave Background . 33 2.4 Primordial Nucleosynthesis (Big Bang Nucleosynthesis - BBN) . 35 3 Structure Evolution 39 3.1 Structure Formation . 39 3.1.1 The Classic Picture . 39 3.1.2 Structure Formation and Cosmology . 41 3.2 Model of the Dark Matter Halo in our Galaxy . 45 3 4 Unsolved Questions and Open Issues 49 4.1 Core-Cusp Problem .
    [Show full text]
  • Evaluating the Viability of Low-Energy Multi-Scattered Neutron
    Evaluation of Low-Energy Multi-scattered Neutron Calibrations for LUX-ZEPLIN A thesis presented for the degree of Bachelor of Science Anna Zuckerman Advisor: Dr. Richard Gaitskell Department of Physics Brown University April 18, 2021 Abstract Over the past several decades, evidence for the existence of dark matter in the uni- verse has become irrefutable. However, the nature of dark matter remains elusive. A prevailing theory is that dark matter takes the form of a Weakly Interacting Mas- sive Particle (WIMP), which could theoretically be detected through various types of experiments. LUX-ZEPLIN (LZ) is one such experiment which seeks to detect WIMPS through the light and charge produced in their collisions with Xenon nuclei in a large underground detector. In order to understand and interpret the results of the LZ experiment, it is important to calibrate the expected light and charge signals for events which deposited known energies into the detector. Thus, various types of calibrations have been developed in the past. However, calibrating for low energies is made difficult by low photon yields, and past calibration techniques have not fully exploited the additional statistics provided by neutrons which scatter multiple times within the detector. This work develops and compares two methods for calibration of the LZ detector at low energies using multi-scattered neutrons. 2 Acknowledgements I would like to thank my advisor Dr. Richard Gaitskell for his guidance and insight over the course of this project. I will take the skills I have learned in this project with me as I continue my academic career. I am also grateful for the help of Casey Rhyne, whose expertise and patience was invaluable to me in starting this project with no prior experience in the field.
    [Show full text]
  • Abstract Contents
    SciPost Phys. 11, 019 (2021) Is a Miracle-less WIMP Ruled out? Jason Arakawa , Tim M.P.Tait Department of Physics and Astronomy, University of California, Irvine, CA 92697-4575 USA Abstract We examine a real electroweak triplet scalar field as dark matter, abandoning the re- quirement that its relic abundance is determined through freeze out in a standard cos- mological history (a situation which we refer to as ‘miracle-less WIMP’). We extract the bounds on such a particle from collider searches, searches for direct scattering with terrestrial targets, and searches for the indirect products of annihilation. Each type of search provides complementary information, and each is most effective in a different region of parameter space. LHC searches tend to be highly dependent on the mass of the SU(2) charged partner state, and are effective for very large or very tiny mass splitting between it and the neutral dark matter component. Direct searches are very effective at bounding the Higgs portal coupling, but ineffective once it falls below 10 3. Indi- λeff ® − rect searches suffer from large astrophysical uncertainties due to the backgrounds and J-factors, but do provide key information for 100 GeV to TeV masses. Synthesizing the allowed parameter space, this example of WIMP∼ dark matter remains viable, but only in miracle-less regimes. Copyright J. Arakawa and T. M. P.Tait Received 13-05-2021 This work is licensed under the Creative Commons Accepted 05-07-2021 Check for Attribution 4.0 International License. Published 03-08-2021 updates Published by the SciPost Foundation. doi:10.21468/SciPostPhys.11.2.019 Contents 1 Introduction2 2 Spin Zero SU(2)-Triplet Dark Matter3 3 Collider Constraints5 3.1 Invisible Higgs Decays5 3.2 Disappearing Tracks5 3.3 Isolated Prompt Leptons6 4 Direct Searches6 5 Indirect Searches8 5.1 Annihilation Cross Sections8 5.2 Sommerfeld Enhancement9 5.3 J Factor 10 5.4 Bounds from Indirect Searches 10 5.5 Constraints from CMB Observables 12 6 Conclusions 13 References 15 1 SciPost Phys.
    [Show full text]
  • The Modern Status of Dark Matter
    Alexey GLADYSHEV Bogoliubov Laboratory of Theoretical Physics, JINR, Dubna OUTLOOK Evidence for the Dark Matter Dark Matter candidates Supersymmetry Dark Matter experiments Indirect detection Direct detection Exclusion limits on DM – nucleon scattering cross-sections and future experiments Conclusion EVIDENCE FOR THE DARK MATTER The Dark Matter is a kind of matter which does not emit or absorb light and cannot be seen even with a telescope We can only detect it with its gravitational effects The nature of the Dark matter is one of the most intriguing puzzles in fundamental physics and cosmology EVIDENCE FOR THE DARK MATTER Orbital velocities of galaxies in clusters (“missing mass”, Zwicky, 1933) Flat rotation curves of spiral galaxies: stars at high radius are faster than expected (Babcock,1939; Rubin, 1970s) EVIDENCE FOR THE DARK MATTER Gravitational lensing of background objects by clusters of galaxies The temperature distribution of the hot gas in galaxies and clusters of galaxies Large scale structure formation Anisotropies in cosmic microwave background EVIDENCE FOR THE DARK MATTER EVIDENCE FOR THE DARK MATTER The Standard Cosmological Model (ΛCDM) The fit to data of different experiments tells us ΩDM = 0.27 DARK MATTER CANDIDATES Particles of the Standard Model Particles of extensions of the Standard Model (heavy neutrinos, Higgs, axion, etc.) Supersymmetric particles (neutralino, axino, gravitino, sneutrino, etc.) Non-particle candidates, e.g. Massive compact halo objects – MACHO New physics mimicking the
    [Show full text]
  • The LZ Dark Matter Experiment Randall Laboratory of Physics, University Ofe-Mail: Michigan, Ann Arbor, Michigan 48109-1040, USA Pos(EPS-HEP2017)072 Z
    The LZ Dark Matter experiment PoS(EPS-HEP2017)072 W. Lorenzon∗† Randall Laboratory of Physics, University of Michigan, Ann Arbor, Michigan 48109-1040, USA E-mail: [email protected] The LUX-ZEPLIN (LZ) experiment is the most advanced next-generation direct detection ex- periment under construction to search for dark matter in the Universe. It contains a dual-phase liquid xenon time projection chamber with a total active mass of 7 tons. LZ is implementing various low background techniques to significantly reduce radioactive background and reach an unprecedented level of sensitivity to spin-independent WIMPs. For a WIMP mass of 40 GeV, a sensitivity of 2:3 × 10−48 cm2 is expected in 1,000 days of operation. LZ will be located at the Sanford Underground Research Facility (SURF) in South Dakota, at the same location as the recently completed LUX experiment. In this presentation, an overview of the experimental techniques and science reach will be presented. The European Physical Society Conference on High Energy Physics 5-12 July, 2017 Venice ∗Speaker. †representing the LZ collaboration c Copyright owned by the author(s) under the terms of the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License (CC BY-NC-ND 4.0). https://pos.sissa.it/ The LZ Dark Matter experiment W. Lorenzon 1. Introduction Overwhelming evidence from astrophysical observations indicates that only 20% of the matter in the universe consists of ordinary matter, while the remaining 80% is made of some form of matter called “dark matter”. Determining the exact nature of this dark matter has emerged as one of the deepest scientific enquiries of our time spanning the fields of cosmology, astrophysics and fundamental particle physics.
    [Show full text]
  • HENRIQUE ARAÚJO Imperial College London (LUX & LZ Collaborations)
    DARK MATTER EXPERIMENTS: QUIET SPACES TO SEARCH FOR BSM PHYSICS HENRIQUE ARAÚJO Imperial College London (LUX & LZ Collaborations) ATOMIC NUCLEI AS LABORATORIES FOR BSM PHYSICS – ECT* TRENTO, APRIL 2019 OUTLINE • Direct dark matter searches • Experimental challenges & opportunities • The noble liquid xenon • Pushing down the energy threshold • The LUX-ZEPLIN (LZ) experiment • Physics from NR and ER interactions Henrique Araújo (Imperial) 2 A DARK UNIVERSE • L-CDM cosmology is a remarkably successful model • Initial conditions photographed at surface of last scatters (CMB) • Left to evolve for 13.7 Gyr under two dark ‘fluids’ – DE and DM • To produce what we see today – normal matter (almost) doesn’t matter { { Henrique Araújo (Imperial) 3 OUR DARK MILKY WAY • Spiral galaxies ‘spin’ too quickly for their observed ‘luminous’ mass • Our Milky Way is no exception: we too are immersed in a DM halo • Direct search experiments probe our galactic DM via elastic scattering • Density near Sun ~0.3 GeV/cm3, mean particle speed v ~ 300 km/s (0.001c) Rubin, et al, 1978, ApJ. Lett. 225, L107 Kafle et al. 2014 ApJ 794 59 Henrique Araújo (Imperial) 4 WEAKLY INTERACTING MASSIVE PARTICLES Main observable: O(keV) nuclear recoils (NR) from elastic WIMP-nucleus scattering Henrique Araújo (Imperial) 5 WIMP-NUCLEUS ELASTIC SCATTERING The ‘spherical cow’ galactic model • DM halo is 3-dimensional, stationary, with no lumps • Isothermal sphere with density profile r ∝ r −2 3 • Local density r0 ~ 0.3 GeV/cm (~1/pint for 100 GeV WIMPs) Maxwellian (truncated) velocity
    [Show full text]
  • Optimization of Signal Versus Background in Liquid Xe Detectors
    Abstract of “Measurement and Analysis of WIMP Detection Backgrounds, and Characteri- zation and Performance of the Large Underground Xenon Dark Matter Search Experiment” by David Charles Malling, Ph.D., Brown University, May 2014. The dominant component of matter in the universe, referred to as dark matter, cannot be explained by the standard model of particle physics. A leading candidate for dark matter is the weakly interacting massive particle (WIMP). The WIMP theory is well motivated by several extensions of the standard model, and has been tested directly in the laboratory over the last 30 years. The Large Underground Xenon (LUX) experiment seeks to identify the signatures of WIMP interactions with baryonic matter. LUX measures particle interactions at the keV level by the detection of single-photon signals in a 250 kg Xe target mass. The LUX detector inner fiducial region is the lowest measured background particle detector in the world at 3 1 1 1 keV energies, with background rates at the level of 10− counts keV− kg− day− . Low background rates are essential for identifying WIMP interactions in the detector, which 1 1 occur with frequencies <1kg− (5 years)− . LUX completed its first low-background science run at the Sanford Underground Re- search Facility in August 2013. WIMP search results are reported from an 85 live day anal- ysis. The experiment places the tightest constraint on WIMP spin-independent interaction cross-sections to date. Results from LUX also exclude several potential dark matter signal claims from other direct detection experiments, for WIMP masses in the range 6–15 GeV.
    [Show full text]
  • Introduction to Class and Dark Matter
    Introduction to Class and Dark Matter Prof. Luke A. Corwin PHYS 792 South Dakota School of Mines & Technology Jan. 14, 2014 (W1-1) L. Corwin, PHYS 792 (SDSM&T) Introduction Jan. 14, 2014 (W1-1) 1 / 22 Outline 1 Introduction to Class 2 Introduction to Dark Matter Evidence for Dark Matter Searching for Dark Matter 3 Reminders L. Corwin, PHYS 792 (SDSM&T) Introduction Jan. 14, 2014 (W1-1) 2 / 22 Introduction to Class You're not Prof. Corwin! Correct, I am not any of the 3 professors named Corwin (Luke, Edward, or Kelly) at Mines Prof. Luke Corwin is in Japan on a research-related trip I have agreed to take over this class for Jan. 14, 16, and 21. Barring unforeseen problems, Prof. L. Corwin will be back for Jan. 23 and most or all of the remainder of the semester. L. Corwin, PHYS 792 (SDSM&T) Introduction Jan. 14, 2014 (W1-1) 3 / 22 Introduction to Class Available on the Class Webpage http://odessa.phy.sdsmt.edu/~lcorwin/PHYS792DM_ Spring2014/ClassWebpage.html The syllabus Past lecture notes (and recordings if possible) All out-of-class homework L. Corwin, PHYS 792 (SDSM&T) Introduction Jan. 14, 2014 (W1-1) 4 / 22 Introduction to Class Mid-term Presentation 20 min. length Select one candidate for dark matter and explain it to the class Your presentation will need to help your fellow students understand the theoretical nature of this candidate and how well (or poorly) it is supported by current experimental data You may choose any candidate except for WIMPs Presentations will be during Week 7 Choose your candidate before or in class on Jan.
    [Show full text]
  • DOE Dark Matter Solicitation Outcome
    DOE Second-Generation Dark Matter Program Status HEPAP Meeting Gaithersburg, MD March 12, 2013 Michael Salamon DOE/Office of High Energy Physics DOE Generation-1 Dark Matter Direct Detection Experiments E. Aprile et al. (2012) -39 ) −36 E. Behnke et al. (2012) 10 2 10 XENON100 (2012) DAMA/Na ] observed limit (90% CL) 2 -40 m 10 Expected limit of this run: CoGeNT [c 1 expected DAMA/I −37 2 expected 10 -41 10 Section XENON10 (2011) -42 CRESST-II (2012) 10 −38 Cross 10 CDF (A−V 10-43 EDELWEISS (2011/12) 100 GeV med.) Nucleon −39 - 10 -44 10 WIMP -45 cMSSM 10 −40 10 2 3 4 Spin−dependentproton cross−section(cm 1 6 7 8 910 20 30 40 50 100 200 300 400 1000 10 10 10 10 WIMP Mass [GeV/c2] WIMP Mass (GeV) PASAG Report (2009) “The panel evaluated the scientific opportunities available under the different budget scenarios. The opportunities include the following: For dark matter direct detection, next-generation (G2) facilities capable of reaching sensitivity levels better than 10-46 cm2 (about a factor of 400 better than present-day limits and a factor ~10 better than expected for the experiments already under construction)... Details are different for different technologies. G2 experiments would have typical target masses of approximately one ton, with a construction and operation cost in the range of $15M-$20M.” Recommendation: In all budget scenarios, “Two G2 experiments and the 100-kg SuperCDMS-SNOLAB experiment are supported.” Recommended G2 construction start in FY13. The three generations a primary selection criterion • DOE/HEP Funding Opportunity Announcement (FOA) for G2 DM experiment R&D: • “For the purposes of this FOA, a second-generation experiment is one that, in the absence of detection, improves our current knowledge of a relevant dark matter particle parameter by roughly one order of magnitude or more.
    [Show full text]