Halide Scintillator Growth & Characterization for Rare Decay Search Presented by Gul Rooh Kyungpook National University Republic of Korea.

Slides:

Advertisements

Similar presentations

1 Proton detection with the R3B calorimeter, two layer solution IEM-CSIC sept report MINISTERIO DE EDUCACIÓN Y CIENCIA CONSEJO SUPERIOR DE INVESTIGACIONES.

Advertisements

Time-of-Flight at CDF Matthew Jones August 19, 2004.

The Detection of Radioisotopes Using a Thin Scintillating Fiber in a Spiral Adam Jernigan and Eric Blue Advisor: Dr. Thomas Dooling The University of North.

Atomic X-Ray Spectroscopy Chapter 12 X-ray range  Å to 100 Å Used  0.1Å to 25 Å.

Analysis and Results 3.Gamma-ray Spectra of 134 Cs The background subtracted spectra of 605 keV and 796 keV in multiple hit events, and their coincidence.

Tests of scintillators CsI, CsI(Na), BGO, NaI(Tl) CsI(Tl)

Observation of Fast Scintillation of Cryogenic PbI 2 with VLPCs William W. Moses, 1* W.- Seng Choong, 1 Stephen E. Derenzo, 1 Alan D. Bross, 2 Robert Dysert,

ipno.in2p3.fr Milano - October 2006IPNO-RDD-Jean Peyré1 Measurements of CsI(Tl) Crystals with PMT and APD Jean Peyré Milano - Oct 2006.

Crystals and related topics J. Gerl, GSI NUSTAR Calorimeter Working Group Meeting June 17, 2005 Valencia.

GAMMA RAY SPECTROSCOPY

Gamma Spectroscopy HPT TVAN Technical Training

Neutron Generation and Detection Lee Robertson Instrument & Source Division Oak Ridge National Laboratory 17 th National School on Neutron and X-ray Scattering.

RAD2012, Nis, Serbia Positron Detector for radiochemistry on chip applications R. Duane, N. Vasović, P. LeCoz, N. Pavlov 1, C. Jackson 1,

Absolute light output determination of crystal scintillators

1 Scintillators  One of the most widely used particle detection techniques Ionization -> Excitation -> Photons -> Electronic conversion -> Amplification.

Department of Radiology UNIVERSITY OF PENNSYLVANIA 1 Investigation of LaBr 3 Detector Timing Resolution A.Kuhn 1, S. Surti 1, K.S. Shah 2, and J.S. Karp.

Dark Matter Search with Direction sensitive Scintillator Ⅱ Department of Physics, School of Science The University of Tokyo Y. Shimizu, M. Minowa, Y. Inoue.

Annual Modulation Study of Dark Matter Using CsI(Tl) Crystals In KIMS Experiment J.H. Choi (Seoul National University) SUSY2012, Beijing.

Half-life It's impossible to predict when a specific atom is going to decay, but you can predict the number of atoms that will decay in a certain time.

Heavy Scintillating Crystal Fibers for calorimetry

2004/Dec/12 Low Radioactivity in CANDLES T. Kishimoto Osaka Univ.

Setup for hypernuclear gamma-ray spectroscopy at J-PARC K.Shirotori Tohoku Univ. Japan for the Hyperball-J collaboration J-PARC E13 hypernuclear  -ray.

Recent status of dark matter search with ULE-HPGe detector Tsinghua University Qian Yue nd Korea-China Joint Seminar on Dark Matter Search.

F. Cappella Univ. La Sapienza e INFN-Roma NPA4 Frascati, June NPA4 Search for double beta decay of zinc and tungsten with low background ZnWO.

THE FAST X-RAY MONITOR (FXM) BASED ON YAP:CE SCINTILLATOR (YTTRIUM ALUMINUM PEROVSKITE ACTIVATED BY CERIUM) FOR THE “CORONAS-PHOTON” SATELLITE PROJECT.

A study on CaMoO4 crystal coupled with LAAPD for neutrinoless double beta decay Sejong University Jung il LEE LEE J.I., BHANG H.C.1, CHOI J.H.1, KIM S.C.1,

Neutron Monitoring Detector in KIMS Jungwon Kwak Seoul National University 2003 October 25 th KPS meeting.

Nuclear Medicine: Planar Imaging and the Gamma Camera Katrina Cockburn Nuclear Medicine Physicist.

SEM- Schematic Overview. Electron Detection Tungsten Filament Electron Source.

Inorganic Scintillators Yeongduk Kim Sejong University

Development of a Gamma Camera Based on an 88 Array of LaBr3(Ce) Scintillator Pixels Coupled to a 64-channel Multi-anode PMT Hidetoshi Kubo, K.Hattori,

KPS Chonbuk University 2005/10/22 HYUNSU LEE Status of the KIMS dark matter search experiment with CsI(Tl) crystals Hyun Su Lee Seoul National.

Medical applications of particle physics General characteristics of detectors (5 th Chapter) ASLI YILDIRIM.

Study of Double Beta Decay of 48 Ca with CANDLES Y.Hirano, T.Kishimoto, I.Ogawa, R.Hazama, S.Umehara, K.Matsuoka, G.Ito, Y.Tsubota, for the CANDLES Collaboration.

Activities on double beta decay search experiments in Korea 1.Yangyang Underground laboratory 2.Double beta decay search with HPGe & CsI(Tl) 3.Metal Loaded.

June INPC20071 Study of 48 Ca double beta decay with CANDLES OGAWA Izumi ( 小川泉 ) Osaka Univ. ( 大阪大学 )

Nuclear Medicine Instrumentation 242 NMT 1 Dr. Abdo Mansour Assistant Professor of radiology

SrCl 2 crystal for EC/  + search Presented by J.H. So (KNU)

PyungChang 2006/02/06 HYUNSU LEE CsI(Tl) crystals for WIMP search Hyun Su Lee Seoul National University (For The KIMS Collaboration)

Sep. 22, 2011 Seoul National University Jae Keum Lee KIMS Background 1 China-Korea Workshop 2011 September 22-23, 2011.

A simulation study on DBD search with pilot setup AMoRE - SNU jilee.

Presented by Jianghua Kyungpook National University 5 th Seminar on Dark Matter Search and Double beta decay, Sept 22-23, 2011, Yangyang, Korea.

The 2 nd HHCAL Workshop, Beijing, China5/9/2010 Search for Scintillation in Doped Lead Fluoride Crystals for the HHCAL Detector Concept Rihua Mao, Liyuan.

DPF-JPS 2006 Oct 31, Hawaii 1 CANDLES system for the study of 48-Ca double beta decay T. Kishimoto Osaka Univ.

CaMoO 4 at low temperature - LAAPD and PMTs - Woonku Kang, Jungil Lee, Eunju Jeon, Kyungju Ma, Yeongduk Kim Sejong University for KIMS collaboration Double.

Development of Plastic Scintillators with Inorganic Powders Yewon Kim, Hyunjun Yoo, Gyuseong Cho, Minsik Cho, Hyoungtaek Kim, Jongyul Kim, Jun Hyung Bae,

Neutrinoless double beta decay (0  ) CdTe Semico nductor Band gap (eV) Electron mobility (cm 2 /V/s) Hole mobility (cm 2 /V/s) Density (g/cm 3.

09/04/2006NDM061 CANDLES for the study of 48 Ca double beta decay OGAWA Izumi ( 小川泉 ) Osaka Univ. ( 大阪大学 )

Gamma Spectrometry beyond Chateau Crystal J. Gerl, GSI SPIRAL 2 workshop October 5, 2005 Ideas and suggestions for a calorimeter with spectroscopy capability.

RDMIS Radiation Detection and Medical Image Sensor lab. Composition Optimization of Polystyrene Based Plastic Scintillator Yewon Kim, Hyunjun Yoo, Chankyu.

WIMPs Direct Search with Dual Light-emitting Crystals Xilei Sun IHEP International Symposium on Neutrino Physics and Beyond

from Saint Gobain studies

Frontier Scintillation Detectors: Inorganic Scintillating Fibers

Institute for Scintillation Materials

Pulse-shape discrimination with Cs2HfCl6 crystal

Activities on double beta decay search at KIMS

Double Beta Decay Experiment with CaMoO4 crystal

Double Beta Decay of 48Ca with CaF2(Eu) - ELEGANT VI -

Status of 100Mo based DBD experiment

Natural CMO+HPGe experiment

R&D status & possible configuration of the 1st round experiment

Irina Bavykina, MPI f. Physik

Sr-84 0n EC/b+ decay search with SrCl2 crystal

Instrument Parameters in WDXRF

Gamma-ray Spectroscopy technique is commonly used in Planetary Exploration Missions.

LSO/LYSO Crystals for Future High Energy Physics Experiments

Characterization of Large CaMoO4 crystals for 0n bb search

Start-Up of a Research Program in Sonoluminescence

Presentation transcript:

Halide Scintillator Growth & Characterization for Rare Decay Search Presented by Gul Rooh Kyungpook National University Republic of Korea

Outline Crystal growing and characterizationCrystal growing and characterization IntroductionIntroduction Properties of an ideal scintillation crystalProperties of an ideal scintillation crystal Crystal growth system by CzochralskiCrystal growth system by Czochralski γ-ray spectroscopy systemγ-ray spectroscopy system Grown crystals using Czochralski method at KNUGrown crystals using Czochralski method at KNU New Czochralski for oxide scintillatorsNew Czochralski for oxide scintillators Bridgman MethodBridgman Method CeBr 3 crystal grown by Bridgman methodCeBr 3 crystal grown by Bridgman method CeBr 3 crystal for 2β +, Kβ + and 2K decay searchCeBr 3 crystal for 2β +, Kβ + and 2K decay search

Crystal growing & characterization Kyungpook National Univ. Pukyong National Univ. Dague Health College Application for radiation detector & medical imagingApplication for radiation detector & medical imaging Application for the rare decay experimentApplication for the rare decay experiment 1.Double beta decay 2.Dark matter search

Introduction To develop new scintillation detectors Determine optimum crystal growing conditions for Determine optimum crystal growing conditions for the single crystals the single crystals Confirmation of the crystal structures using XRD Confirmation of the crystal structures using XRD Measurement of the emission spectra Measurement of the emission spectra Measurement of the scintillation properties Measurement of the scintillation properties  Pulse height spectra for different radioisotopes  Light yield  Proportionality curve  Energy resolution  Fluorescence decay time  α/β ratio

Important properties of an ideal scintillation crystal High Density and atomic number (Z)High Density and atomic number (Z) High Light output ->good energy resolutionHigh Light output ->good energy resolution Decay time (duration of the scintillation light pulse)Decay time (duration of the scintillation light pulse) Mechanical and optical propertiesMechanical and optical properties Radiation damage hardnessRadiation damage hardness CostCost

Crystal growth system by Czochralski Pt BAR & Pt WIRE SEED ALUMINA TUBE WINDOW CRYSTAL R.F. COIL THERMO COUPLE Pt CRUCIBLE FIRE-BRICK OutsideInside

Czochralski crystal growth process Weighing Cutting Growing 3 mm/hr 25 rpm in Ar Polishing 10 ⅹ 10 ⅹ 10 mm 3

Grown crystals using Czochralski & Bridgman method at KNU PbCl 2 :Eu CsI PbCl 2 CsSrCl 3 CsCl 3 :Ce LaCl 3 :Ce SrCl 2 :Eu Ba x Sr 1-x Cl 2

γ-ray spectroscopy system Crystal PMT 400 MHz FADC High Voltage Computer Root Dark Box FADC Pre-Amp Oscilloscope

CsCl 3 :Ce with 137 Cs γ- rays By Jinho Moon

LaCl 3 :Ce 3+ with 137 Cs γ- rays By Jinho Moon

Energy resolution & light yield of the SrCl 2 :Eu 2+ depending on Eu 2+ concentrations By Jinho Moon

New Czochralski for Oxide scintillators Today we have new czochralski for bigger crystals and high melting point powders i.e. Oxides.Today we have new czochralski for bigger crystals and high melting point powders i.e. Oxides. It is under observation for the temperature controlling.It is under observation for the temperature controlling. 10 times bigger

Bridgman Method

CeBr 3 by Bridgman Method Short decay time <20nsShort decay time <20ns Good energy resolution (5% FWHM)Good energy resolution (5% FWHM) By Sejin Ra

Relative light yield of CeBr 3 single crystal with Bialkali PMT

CeBr 3 for 2β +, Kβ + and 2K decaysearch CeBr 3 for 2β +, Kβ + and 2K decay search 136 Ce has Q-value = 2400keV 136 Ce has Q-value = 2400keV Natural abundance =0.185%Natural abundance =0.185% Exp: calculated half life for 0vExp: calculated half life for 0v  6.9x10 17 yrs (2β + ) (By Bernabei et.al)  3.8x10 16 yrs (Kβ + ) (By Danevich et.al)  6.0x10 15 yrs (2K) (By Danevich et.al) Under investigation for rare decaysearch at Y2L lab.Under investigation for rare decay search at Y2L lab. SrCl 2 (Pure) single crystal for EC/ β + (Presented by J.H.So)SrCl 2 (Pure) single crystal for EC/ β + (Presented by J.H.So)

Summary To develop new halide scintillators for nuclear & high energy physics experiments & medical imaging.To develop new halide scintillators for nuclear & high energy physics experiments & medical imaging. Crystal growth system by CzochralskiCrystal growth system by Czochralski γ-ray spectroscopy systemγ-ray spectroscopy system Some developed crystals by CZ technique at KNUSome developed crystals by CZ technique at KNU New CZ for Oxides and bigger crystals growthNew CZ for Oxides and bigger crystals growth Bridgman MethodBridgman Method CeBr 3 crystal scintillation properties and for the study of rare decay searchCeBr 3 crystal scintillation properties and for the study of rare decay search

Number of nuclei of Ce in GSO:Ce =4.1 × Emission wavelength of CsI:Tl =540nm

CeBr3