DARWIN. Marc Schumann Physik Institut, Universität Zürich. Aspera Technology Forum 2010, October 21-22, 2010

Similar documents
DARWIN: DARk matter WImp search with Noble liquids

DARWIN: dark matter WIMP search with noble liquids

XENON100. Marc Schumann. Physik Institut, Universität Zürich. IDM 2010, Montpellier, July 26 th,

Prospects for WIMP Dark Matter Direct Searches with XENON1T and DARWIN

Dark Matter and the XENON Experiment

Direct WIMP Detection in Double-Phase Xenon TPCs

Direct dark matter search using liquid noble gases

WIMP Dark Matter Search with XENON and DARWIN

Dark Matter Search with XENON

Light Dark Matter and XENON100. For the XENON100 Collaboration Rafael F. Lang Columbia University

Direct dark matter search using liquid noble gases

Development of the GridPix Detector for Dual Phase Noble Gas Time Projection Chambers

The XENON1T experiment

the DarkSide project Andrea Pocar University of Massachusetts, Amherst

R&D on Astroparticles Detectors. (Activity on CSN )

PoS(EPS-HEP2017)074. Darkside Status and Prospects. Charles Jeff Martoff Temple University

The ArDM project: A Liquid Argon TPC for Dark Matter Detection

Direct detection: results from liquid noble-gas experiments

PANDA-?? A New Detector for Dark Matter Search

DARWIN. Marc Schumann. U Freiburg PATRAS 2017 Thessaloniki, May 19,

Dark Matter search with liquid xenon: from XENON100 to next generation experiments. Presented by Samuel DUVAL

DARWIN. Marc Schumann. U Freiburg LAUNCH 17 Heidelberg, September 15,

Dark Matter Detection and the XENON Experiment. 1 Abstract. 2 Introduction

The XENON Project. M. Selvi The XENON project

XENONNT AND BEYOND. Hardy Simgen. WIN 2015 MPIK Heidelberg. Max-Planck-Institut für Kernphysik Heidelberg

Measurement of the transverse diffusion coefficient of charge in liquid xenon

Low Energy Particles in Noble Liquids

The XENON Dark Matter Project: Status of the XENON100 Phase. Elena Aprile Columbia University

Measurement of 39 Ar in Underground Argon for Dark Matter Experiments

The XENON1T Experiment

Measurements of liquid xenon s response to low-energy particle interactions

arxiv:astro-ph/ v1 15 Feb 2005

PANDA-X A New Detector for Dark Matter Search. Karl Giboni Shanghai Jiao Tong University

DarkSide new results and prospects

Factors Affecting Detector Performance Goals and Alternative Photo-detectors

The ArDM Experiment. A Double Phase Argon Calorimeter and TPC for Direct Detection of Dark Matter

Understanding the response of LXe to electronic and nuclear recoils at low energies

DarkSide. Bianca Bottino Università di Genova and INFN Sezione di Genova on behalf of the DarkSide collaboration 1

LUX: A Large Underground Xenon detector. WIMP Search. Mani Tripathi, INPAC Meeting. Berkeley, May 5, 2007

Status of the XENON100 Dark Matter Search

DarkSide-50: performance and results from the first atmospheric argon run

The Dual-Phase Liquid Xenon Time Projection Chamber (TPC) of Münster

The XENON100 Dark Matter Experiment at LNGS: Status and Sensitivity

Direct Dark Matter Search with Noble Liquids

- JRA2 ADVANCED TECHNIQUES FOR RARE EVENT DETECTION Tentative structure

Charge readout and double phase

Scintillation Efficiency of Nuclear Recoils in Liquid Xenon. T. Wongjirad, L. Kastens, A. Manzur, K. Ni, and D.N. McKinsey Yale University

DarkSide-20k and the Darkside Program for Dark Matter Searches

Paolo Agnes Laboratoire APC, Université Paris 7 on behalf of the DarkSide Collaboration. Dark Matter 2016 UCLA 17th - 19th February 2016

Supernova Neutrino Physics with XENON1T and Beyond

LARGE UNDERGROUND XENON

Background and sensitivity predictions for XENON1T

Technical Specifications and Requirements on Direct detection for Dark Matter Searches

The Search for Dark Matter with the XENON Experiment

Status of DM Direct Detection. Ranny Budnik Weizmann Institute of Science

Laboratori Nazionali del GranSasso Alfredo G. Cocco Istituto Nazionale di Fisica Nucleare Sezione di Napoli

The ArDM Project a Direct Detection Experiment, based on Liquid Argon, for the Search of Dark Matter

Micro Pixel Chamber Operation with Gas Electron Multiplier

The LZ Experiment Tom Shutt SLAC. SURF South Dakota

DarkSide-20k and the future Liquid Argon Dark Matter program. Giuliana Fiorillo Università degli Studi di Napoli Federico II & INFN Napoli

The next generation dark matter hunter: XENON1T status and perspective

X-ray ionization yields and energy spectra in liquid argon

Backgrounds and Sensitivity Expectations for XENON100

TitleDevelopment of an MeV gamma-ray ima. works must be obtained from the IEE

arxiv: v2 [physics.ins-det] 30 Jul 2012

Xenon Compton Telescopes at Columbia: the post LXeGRIT phase. E.Aprile. Columbia University

Dark Matter Detection with XENON100 Accomplishments, Challenges and the Future

PandaX Dark Matter Search

Direct Dark Matter Searches

Detectors for astroparticle physics

After LUX: The LZ Program. David Malling, Simon Fiorucci Brown University APS DPF Conference August 10, 2011

Current status of LUX Dark Matter Experiment

Studies of the XENON100 Electromagnetic Background

The Neutron/WIMP Acceptance In XENON100

nerix PMT Calibration and Neutron Generator Simulation Haley Pawlow July 31, 2014 Columbia University REU, XENON

Recent results from PandaX- II and status of PandaX-4T

Particle Energy Loss in Matter

PandaX detector calibration and response. 报告人 : 肖梦姣 Shanghai Jiao Tong University (On behalf of the Panda-X Collaboration)

Recent results from the UK Dark Matter Search at Boulby Mine.

X-ray ionization yields and energy spectra in liquid argon

Performance of the Gamma-ray Imaging Detector with Micro-TPC

XENON1T: opening a new era in the search for Dark Matter. Elena Aprile, Columbia University on behalf of the Collaboration, UCLA, February 17, 2016

The XENON dark matter search. T. Shutt CWRU

Shedding Light on Dark Matter from Deep Underground with XENON. Kaixuan Ni (Columbia)

Background Studies for the XENON100 Experiment. Alexander Kish Physics Institute, University of Zürich Doktorandenseminar August 30, 2010 UZH

Prospects for kev-dm searches with the GERDA experiment

Optical readout of secondary scintillation from liquid argon generated by a thick gas electron multiplier

DARK MATTER SEARCH AT BOULBY MINE

Dark Matter Direct Detection

PMT Calibration and Neutron Generator Simulation for nerix

PHOTOELECTRON COLLECTION EFFICIENCY AT HIGH PRESSURE FOR A GAMMA DETECTOR ENVISAGING MEDICAL IMAGING

Detecting low energy recoils with Micromegas

DUNE detector design and lowenergy reconstruction capabilities. Inés Gil Botella

Search for Inelastic Dark Matter with the CDMS experiment. Sebastian Arrenberg Universität Zürich Doktorierendenseminar 2010 Zürich,

arxiv: v1 [physics.ins-det] 31 Oct 2015 Alden Fan 1

SIGN: A Pressurized Noble Gas Approach to WIMP Detection

Oddities of light production in the noble elements. James Nikkel

The XENON100 Dark Matter Experiment

The DarkSide-50 Outer Detectors

XENON Dark Matter Search. Juliette Alimena Columbia University REU August 2 nd 2007

Transcription:

21-22 DARWIN Marc Schumann Physik Institut, Universität Zürich Aspera Technology Forum 2010, October 21-22, 2010 www.physik.uzh.ch/groups/groupbaudis/xenon/

Dark Matter: Evidence & Detection NASA/WMAP Direct Detection: Elastic Scattering of WIMPs off target nuclei nuclear recoil WIMP WIMP v ~ 230 km/s ER ~ O(10 kev) 2

DARWIN - Overview Xenon 2010-2020 XENON Argon WARP ArDM DARWIN Dark Matter WIMP Search with Noble Liquids R&D and Design Study for a next generation noble liquid facility in Europe. Approved by ASPERA in late 2009 Coordinate existing European activities in LXe and LAr towards a multi-ton Dark Matter facility Physics goal: probe WIMP cross sections well below 10 47 cm² 3

DARWIN: Dual Phase TPC Anode Cathode ionization/scintillation ratio (S2/S1) allows electron recoil rejection to >99.5% 3D position reconstruction in TPC Pulse Shape Discrimination in LAr 4

Goals and Structure R&D and Design Study for Light/Charge Readout, Electronics/DAQ, Detector/Underground/Shield Infrastructure, Material Screening/Backgrounds, Science Impact Multiton LXe and/or LAr WIMP detector find best choice/design, exploit complementarity? 22 groups ArDM, WARP, XENON Groups: UZH (CH), INFN (I), ETHZ (CH), Subatech (F), Mainz (D), MPIK (D), Münster (D), Nikhef (NL), KIT (D), IFJPAN (PL) + Columbia, Princeton, UCLA (USA) http://darwin.physik.uzh.ch 5

DARWIN is a Design Study for a next-to-next generation Dark Matter detection experiment based on LXe/LAr Most technical requirements have not beed defined yet. They are the outcome of the DARWIN study. 6

Key Requirements: - lowest radioactivity - large number of channels [~O(1000) large data amount] - high sensitivity (QE) in order to reach low threshold - large area sensors - operation in cryogenic liquid - moderate cost 3 Workpackages (WP) 7

WP3: Light Readout Classic Approach: The same photosensors detect S1 (light) and S2 (charge) signal. Photodetectors (a) large area PMTs - low radioactivity - high QE, high collection efficiency - operation at cryogenic temperatures (b) hybrid detectors with large cathode and solid state e-multiplier (QUPID) - extremely low radioactivity - for LXe and LAr UV light collection (a) co-doping of Ar with Xe ( shift light emission) (b) LAr: wavelength shifters, coating of light sensors (c) surface properties of materials (reflection, diffusion) (d) 4 geometry: challenges? Light guides? 8

WP4: Alternative Charge Readout Idea: - good position resolution for signal / background discrimination - charge cloud in TPC is very localized (<1 mm) - large scale charge readout structures can keep this information Goal: Investigate and develop new concepts for readout of ionization produced in kev energy events, independent of scintillation readout. Approach: (a) Large cryogenic LEM / THGEM / Micromegas for noble liquids charge amplification in holes (GEM) (b) Gaseous PMTs without dead zone separation with MgF4 window allows use of quencher (c) CMOS pixel detector coupled to electron multipliers (GridPix) low radioactivity is possible 9

WP5: Electronics, DAQ Goal: identify electronics, DAQ, and data processing solutions for large-scale noble liquid experiments 1. Low noise electronics for light and charge readout - amplifiers for QUPIDs / charge readout structures FADCs: large bandwidth and fast sampling (100 MHz 1 GHz) intelligent data reduction algorithms (long drift times) cabling studies ( purity, cross talk) study possibility to digitize directly on sensor 2. DAQ and trigger - intelligent trigger, multi-stage trigger multi-hit veto, high energy veto, first online analysis 3. Common computing resource center - increased demand for computing power MC, data storage, duplication, processing, analysis 10

Summary DARWIN: a multiton LXe/LAr detector to explore cross sections well below 10 47 cm² design study approved by ASPERA, timeline 2010 end 2012 outcome will be a proposal for the DARWIN facility Technical Challenges: - lowest radioactivity - large number of channels - high sensitivity (QE) - large area sensors - operation in cryogenic liquid - moderate cost XENON100 XENON1T DARWIN http://darwin.physik.uzh.ch 11

2024 © sciencedocbox.com Privacy Policy | Terms of Service | Feedback