2009. 10. 22 KIMS Seoul National University Juhee Lee 1 KPS in Changwon.

Slides:

Advertisements

Similar presentations

Electron Recoil & Dark Matter Direct Detection

Advertisements

Dante Nakazawa with Prof. Juan Collar

Study of plastic scintillators for fast neutron measurements

Ion Beam Analysis techniques:

Geiger-Muller detector and Ionization chamber

Introducing Channeling Effect

Status of Ultra-low Energy HPGe Detector for low-mass WIMP search Li Xin (Tsinghua University) KIMS collaboration Oct.22nd, 2005.

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.

Study of sputtering on thin films due to ionic implantations F. C. Ceoni, M. A. Rizzutto, M. H. Tabacniks, N. Added, M. A. P. Carmignotto, C.C.P. Nunes,

S. Zuberi, University of Rochester Digital Signal Processing of Scintillator Pulses Saba Zuberi, Wojtek Skulski, Frank Wolfs University of Rochester.

30 Ge & Si Crystals Arranged in verticals stacks of 6 called “towers” Shielding composed of lead, poly, and a muon veto not described. 7.6 cm diameter.

Radiation therapy is based on the exposure of malign tumor cells to significant but well localized doses of radiation to destroy the tumor cells. The.

Stopping Power The linear stopping power S for charged particles in a given absorber is simply defined as the differential energy loss for that particle.

ECE/ChE 4752: Microelectronics Processing Laboratory

Workshop on Physics on Nuclei at Extremes, Tokyo Institute of Technology, Institute for Nuclear Research and Nuclear Energy Bulgarian Academy.

Lee, Myeong Jae DMRC, Seoul national university

Study of plastic scintillator quenching factors Lea Reichhart, IOP Glasgow, April /17.

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

Space Instrumentation. Definition How do we measure these particles? h p+p+ e-e- Device Signal Source.

Study of the Halo Nucleus 6 He using the 6 Li(   ) 6 He Reaction Derek Branford - Edinburgh University for the A2-Collaboration MAMI-B Mainz.

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

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

Neutron scattering systems for calibration of dark matter search and low-energy neutrino detectors A.Bondar, A.Buzulutskov, A.Burdakov, E.Grishnjaev, A.Dolgov,

Ultra-low background HPGe detector at ChyeongPyung Underground Laboratory TaeYeon Kim and KIMS(Korea Invisible Mass Search) Collaboration. * Contents *

Iwha Womans University 2005/04/22 Hyunsu Lee & Jungwon Kwak Current Limit of WIMP search with CsI(Tl) crystal in KIMS 이현수 *, 곽정원, 김상열, 김선기, 김승천,

The Recent Status of KIMS Group and New Plan Li Xin (Tsinghua University) KIMS collaboration Aug. 28th, 2006.

J.T. White Texas A&M University SIGN (Scintillation and Ionization in Gaseous Neon) A High-Pressure, Room- Temperature, Gaseous-Neon-Based Underground.

A Study of Background Particles for the Implementation of a Neutron Veto into SuperCDMS Johanna-Laina Fischer 1, Dr. Lauren Hsu 2 1 Physics and Space Sciences.

1 dE/dx  Let’s next turn our attention to how charged particles lose energy in matter  To start with we’ll consider only heavy charged particles like.

The Simulation of the quenching factor and the channeling effect for the CsI(Tl) and NaI(Tl) crystals Juhee Lee and Sunkee Kim Seoul National University.

Radiation damage calculation in PHITS

KIMS collaboration S. Ryu,. 2th Korea-China joint workshop 2007Collaboration Meeting  Rotation curve of Spiral Galaxies  Cosmic microwave.

Meta-stable Sites in Amorphous Carbon Generated by Rapid Quenching of Liquid Diamond Seung-Hyeob Lee, Seung-Cheol Lee, Kwang-Ryeol Lee, Kyu-Hwan Lee, and.

Measurement of J/  -> e + e - and  C -> J/  +   in dAu collisions at PHENIX/RHIC A. Lebedev, ISU 1 Fall 2003 DNP Meeting Alexandre Lebedev, Iowa State.

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.

Muon and Neutron Backgrounds at Yangyang underground lab Muju Workshop Kwak, Jungwon Seoul National University 1.External Backgrounds 2.Muon.

Validation of EM Part of Geant4

Dark Matter Search with Direction Sensitive Scintillators The10th ICEPP Symposium February 16, 2004, Hakuba H. Sekiya University of Tokyo.

Daily Modulation of the Dark Matter Signal in Crystalline Detectors Nassim Bozorgnia UCLA TexPoint fonts used in EMF. Read the TexPoint manual before you.

WIMP search Result from KIMS experiments Kim Seung Cheon (DMRC,SNU)

00 Cooler CSB Direct or Extra Photons in d+d  0 Andrew Bacher for the CSB Cooler Collaboration ECT Trento, June 2005.

Frictional Cooling A.Caldwell MPI f. Physik, Munich FNAL

2001 Mars Odyssey page 1 W o r k s h o p H E N D Institute for Space Research, June , 2003 HEND physical calibrations: status report A. Kozyrev,

CsI Veto Detector Performance Study He Dao DMRC. Tsinghua University For KIMS Collaboration.

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

Seoul National University Han-wool Ju CUNPA Kick-off Meeting Aug.22-23, 2013.

Jun Chen Department of Physics and Astronomy, McMaster University, Canada For the McMaster-NSCL and McMaster-CNS collaborations (5.945, 3+ : **) (5.914,

Scintillating Bubble Chambers for Direct Dark Matter Detection Jeremy Mock On behalf of the UAlbany and Northwestern Groups 1.

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

Ion Implantation CEC, Inha University Chi-Ok Hwang.

Status of ULE-HPGe Experiment for WIMP Search in YangYang

KIMS & Inelastic DarK Matter(iDM)

Relativistic Kinematics for the Binding Energy of Nuclear Reactions

Fast neutron flux measurement in CJPL

12th Geant4 Space Users Workshop

INTERACTION OF PARTICLES WITH MATTER

Jing Liu Kavli IPMU, University of Tokyo 8 Apr. 2013, Tuebingen

Neutral Particles.

Fluctuation of track structure in terms of distribution of excitations and fractal dimensions A.Vasil’ev Skobeltsyn Institute of Nuclear Physics of Lomonosov.

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

Monte Carlo studies of the configuration of the charge identifier

R. Bucˇık , K. Kudela and S. N. Kuznetsov

Sang-Pil Kim1,2, Kwang-Ryeol Lee1, Jae-Sung Kim3 and Yong-Chae Chung2

PARTICLE FLUX CALCULATION-III

Neutron Detection with MoNA LISA

1. Introduction Secondary Heavy charged particle (fragment) production

Status of Neutron flux Analysis in KIMS experiment

Neutron Beam Test for Measuring Quenching Factor of CsI(Tl) Crystal

Yue, Yongpyung, Korea Prospects of Dark Matter Search with an Ultra-Low Threshold Germanium Detector Yue, Yongpyung, Korea

The Estimated Limits For A 5g LE-Ge Detector

Presentation transcript:

KIMS Seoul National University Juhee Lee 1 KPS in Changwon

Contents ① Motivation & Objectives ② Introduction to channeling effect ③ Investigation methods ④ Validity of our methods ⑤ Results ⑥ Conclusion ⑦ Summary ⑧ References KPS in Changwon2

Motivation KIMS (Korea Invisible matter search) has been trying to see the WIMP signal with CsI(Tl) crystal. We use PSD (Pulse Shape Discrimination) method to discriminate nuclear events with the gamma background. DAMA saids that there is the channeling effect in crystal detector which induces higher quenching factor in nuclear events with some probability, so PSD method will remove that kind of real events. [1] KPS in Changwon3

Objectives How much the channeling effect can we expect in CsI(Tl)? Can we measure that kind of event? KPS in Changwon4

Introduction to the channeling effect KPS in Changwon5 Channeling effect? : If the direction of a charged particle incident upon the surface of a crystal lies close to a major crystal direction, the particle suffer a small angle scattering passing through several hundreds or thousand of lattice spacing. [2] (a) Channeling effect (b) Blocking effect

Measurement of the channeling effect[2] KPS in Changwon 6 Introduction to the channeling effect (a) photographic reproduction (b) radial projection of the (111) face of the fcc crystal

Calculated interatomic potential[2] V(r) = (Z 1 Z 2 e 2 /r)  (r/a),  (r/a) : screening function KPS in Changwon7 Introduction to the channeling effect (a) I -> Ag target R - target atom’s position dot - the minima of potential

Calculation of the Channeling effect[1] C : 3 1/2 a TF : The screening length of Tomas-Fermi interaction d : Interatomic spacing E : Ion’s kinetic energy KPS in Changwon8 Introduction to the channeling effect

Investigation Methods Quenching Factor = Emeasured / Erecoil : Emeasured is reproduced by “Sum of Ionization energy * Scintillation efficiency at each penetration depth”. Scintillation efficiency according to Stopping power ( MeV cm 2 / g) (a) CsI(Tl) : Tl mole%[3] (b) NaI(Tl) : Tl ~0.1mole%[4] KPS in Changwon9

Investigation Methods Ionization energy at each penetration depth (1) SRIM (The Stopping power and Range of Ions in Matter) [5] (2) MARLOWE (Computer Simulation of Atomic Collision in Crystalline Solids Ver. 15b) [6] KPS in Changwon 10

Investigation Methods Comparing quenching factors of SRIM & MARLOWE for CsI(Tl) (a) Stopping power distribution (b) Quenching factors for CsI(Tl) for the amorphous target KPS in Changwon11 SRIM MARLOWE [7] [9] [8] [3] [11] [10]

Validity of our methods Comparing of Ranges of MARLOWE & Experiments[11] ( Ion : 40keV 85 Kr +, Target : Al ) (a) Stopping power distribution (b) Ranges for the amorphous target KPS in Changwon12 SRIM MARLOWE Al 7  from Al Al Polycrystalline Al Amorphous Al2O3 Amorphous Al (b)

Results Critical angle for CsI(Tl) Event selection – “Total ionization energy loss>Recoil energy/4” ex.) Cs 5keV in CsI(Tl) KPS in Changwon13 [111] [100] [110] [100]  : 4.89 

Results Critical angle for CsI(Tl ) (black : calculation, red: simulation) KPS in Changwon14 1keV5keV10keV15keV20keV50keV [111] [100] [110]

Results Events due to the channeling effect in CsI(Tl) in the neutron induced nuclear events KPS in Changwon15 (a) Radial penetration : depE (b) Measured E The amount of tail is ~2%

Results Quenching factor (a) (Simulation) Emeasured (b) (Simulation) Emeasured with external ions penetrating with a lattice ion penetrating symmetric axis symmetric axis KPS in Changwon16

Results Critical angle & channeling effect of NaI(Tl) for I ion of 4keV KPS in Changwon17 Ref.[13]MARLOWE [100] 6.4  [110] 4.9  [111] 2.8  (100) 4.1  (110) 3.2  (111) 2.7  Channeling effect~20%4.1%

Conclusion In the case of Cs ion penetrating CsI(Tl) with few tens of keV, The simulated critical angle of most open axis is larger than the others. But its energy dependence is different from the calculated one. Although the angle from symmetric axis is in the critical angle, the probability of the dechanneling is significant. And the lower the ion’s energy, the higher the probability. The recoil ion on a lattice site have less probability to be channeled than the incoming one from outside. If this simulation is similar with the real situation, we cannot discriminate the channeling event in the nuclear event. KPS in Changwon18

Summary KPS in Changwon19 ① We check the possibility to use scintillation efficiency curve to simulate the measured energy and quenching factor. ② SRIM can reproduce the range and energy loss of an ion penetrating an amorphous target. ③ MARLOWE has the merit to reproduce the crystal effect and estimate the channeling effect. ④ The experiment of channeling effect with neutrons is need to tell whether these results are true or not.

References [1] Eur. Phys. J. C 53 (2008) 205 [2] Rev. Mod. Phys. Vol. 46, No.1 (1974) [3] Phys. Rev. Vol. 131, No.2 (1963) [4] Phys. Rev. Vol. 122, No.3 (1961) [5] [6] www-rsicc.ornl.gov /rsiccnew/ CodesAvailableElsewhere.htm [7] Phys. Lett. B 536 (2002) 203 [8] Nucl. Inst. Meth. A 491 (2002) 460 KPS in Changwon20

References [9] Astro. Phys. 11 (1999) 457 [10] Nucl. Instrum. Meth. A 557 (2006) 490 [11] Nucl. Instrum. Meth. A 500 (2003) 337 [12] Phys. Rev. Lett. Vol.10 (1963) 399 [13] arXiv: v2 KPS in Changwon21