THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Recent Advances in THGEM Detectors M. Cortesi, A. Breskin, R. Chechik, R. Alon, J. Miyamoto Weizmann.

Slides:

Advertisements

Similar presentations

First observation of electroluminescence in liquid xenon within THGEM holes: towards novel Liquid Hole-Multipliers L. Arazi, A. Breskin, A. Coimbra*,

Advertisements

CBM Jammu University Feb , 2008 by Arun Prakash CBM Banaras Hindu University Arun Prakash DoP, BHU (For Banaras Group) Out.

Beijing, August 18, 2004 P. Colas - Micromegas for HEP 1 Recent developments of Micromegas detectors for High Energy Physics Principle of operationPrinciple.

GEM Detector Shoji Uno KEK. 2 Wire Chamber Detector for charged tracks Popular detector in the particle physics, like a Belle-CDC Simple structure using.

A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs A. Breskin, A. Lyashenko, R. Chechik Weizmann Institute of Science, Rehovot, Israel J.M.F. dos Santos,

GEM DHCAL Simulation Studies J. Yu* Univ. of Texas at Arlington ALCW, July 15, 2003 Cornell University (*on behalf of the UTA team; S. Habib, V. Kaushik,

Linear Collider TPC R&D in Canada Madhu Dixit Carleton University.

Micro Pattern Gas Detector Technologies and Applications The work of the RD51 Collaboration Marco Villa (CERN), Andrew White (University of Texas at Arlington)

Detectors for Tomorrow and After Tomorrow… Amos Breskin Radiation Detection Physics Group Weizmann Institute 1 Amos Breskin.

Detector R & D plan Detector Development plan Detector Simulations Conclusion SINP/VECC Meeting High Energy Physics Group, BHU.

Sept. 24, Status of GEM DHCAL Jae Yu For GEM-TGEM/DHCAL Group Sept. 24, 2010 CALICE Collaboration Meeting Univ. Hassan II, Casablanca Introduction.

C.Shalem et al, IEEE 2004, Rome, October 18 R. Chechik et al. ________________RICH2004_____________ Playa del Carmen, Mexico 1 Thick GEM-like multipliers:

The work of GEM foil at CIAE

WG1 summary P. Colas, S. Duarte Pinto RD51 Collaboration meeting in Bari October 7-10, 2010.

A. Breskin RD51 Amsterdam 4/08 ION BLOCKING & visible-sensitive gas-PMs Efficient ion blocking in gaseous detectors and its application to visible-sensitive.

A. Lyashenko INSTR08 – BINP – Feb ION BLOCKING & visible-sensitive gas-PMs Efficient ion blocking in gaseous detectors and its application to visible-sensitive.

RICH04 Mexico A. Breskin Ion-induced effects in GEM & GEM/MHSP- gaseous photomultipliers for the UV & visible spectral range

Gaseous photomultipliers and liquid hole-multipliers for future noble-liquid detectors L. Arazi [1], A. E. C. Coimbra [1,2], E. Erdal [1], I. Israelashvili.

1 The GEM Readout Alternative for XENON Uwe Oberlack Rice University PMT Readout conversion to UV light and proportional multiplication conversion to charge.

GEM Digital Hadron Calorimetry

Fabio Sauli-CERN 1 IEEE-NSS Rome 04 F. Sauli, T. Meinschad, L. Musa, L. Ropelewski CERN, GENEVA, SWITZERLAND PHOTON DETECTION AND LOCALIZATION WITH THE.

THGEM “news” Mostly Ne-mixtures… Weizmann M. Cortesi, J. Miyamoto, R. Chechik, A. Layshenko CERN V. Peskov Coimbra & Aveiro J. Veloso, C. Azevedo, J. Escada,

LRT2004 Sudbury, December 2004Igor G. Irastorza, CEA Saclay NOSTOS: a spherical TPC to detect low energy neutrinos Igor G. Irastorza CEA/Saclay NOSTOS.

GEM: A new concept for electron amplification in gas detectors Contents 1.Introduction 2.Two-step amplification: MWPC combined with GEM 3.Measurement of.

DEVELOPMENT OF A THGEM-BASED PHOTON DETECTOR FOR CHERENKOV IMAGING APPLICATIONS Silvia Dalla Torre INFN - Trieste On behalf of an Alessandria-CERN-Freiburg-Liberec-Prague-Torino-TriesteCollaboration.

F.Murtas1IMAGEM DDG GEM technology for X-ray and Gamma imaging IMAGEM l Detector setup l First results on X-ray imaging l First results on Gamma ray imaging.

Wir schaffen Wissen – heute für morgen 10 th RD51 Collaboration Meeting, Stony Brook University, USA Progress in Fast-Neutron THGEM Detector for Fan-Beam.

R & D at BHU B.K. Singh (On behalf of HEP Group).

Working Group 1 WG1 Geometry and Interactions Technological Aspects and Developments of New Detector structures.

THGEM in Ne-mixtures UV-photon detection in RICH & more Weizmann: M. Cortesi, R. Chechik, R. Budnik, CERN: V. Peskov Coimbra & Aveiro: J. Veloso, C. Azevedo,

RD51 Collaboration: Development of Micro-Pattern Gaseous Detectors technologies Matteo Alfonsi (CERN) on behalf of RD51 Collaboration Current Trends in.

Rachel Chechik Weizmann Institute TIIPP09 Tsukuba March 2009 The THGEM: a THick robust Gaseous Electron Multiplier for radiation detectors A.Breskin, M.

Development of Digital Hadron Calorimeter Using GEM Shahnoor Habib For HEP Group, UT Arlington Oct. 12, 2002 TSAPS Fall ’02, UT Brownsville Simulation.

6-Aug-02Itzhak Tserruya PHENIX Upgrade mini-Workshop1 Boris Khachaturov, Alexander Kozlov, Ilia Ravinovich and Itzhak Tserruya Weizmann Institute, Israel.

Itzhak Tserruya, BNL, May13, HBD R&D Update: Demonstration of Hadron Blindness A. Kozlov, I. Ravinovich, L. Shekhtman and I. Tserruya Weizmann Institute,

Study of TGEMs and RETGEMs for the possible ALICE upgrade By Himank Anand and Isha Shukla (CERN summer students) Supervisor :Vladimir Peskov.

TPC/HBD R&D at BNL Craig Woody BNL Mini Workshop on PHENIX Upgrade Plans August 6, 2002.

Working Group 1 Technological Aspects and Developments of New Detector structures WG1 Geometry and Interactions.

Future Possibilities for Measuring Low Mass Lepton Pairs in Christine Aidala for the Collaboration Quark Matter 2002, Nantes.

Development of Au-coated THGEM for Single Photon, Charged Particle, and Neutron Detection Yuguang Xie a *, Junguang Lv a, Aiwu Zhang a, Boxiang Yu a, Tao.

Update on GEM-based Calorimetry for the Linear Collider A.White 1/11/03 (for J.Yu, J.Li, M.Sosebee, S.Habib, V.Kaushik)

1 Two-phase Ar avalanche detectors based on GEMs A. Bondar, A. Buzulutskov, A. Grebenuk, D. Pavlyuchenko, Y. Tikhonov Budker Institute of Nuclear Physics,

A.Ochi Kobe University MPGD2009 Crete 13 June 2009.

1 A two-phase Ar avalanche detector with CsI photocathode: first results A. Bondar, A. Buzulutskov, A. Grebenuk, D. Pavlyuchenko, R. Snopkov, Y. Tikhonov.

Update on THGEM project for RICH application Elena Rocco University of Eastern Piedmont & INFN Torino On behalf of an Alessandria-CERN-Freiburg-Liberec-

Recent THGEM investigations A. Breskin, V. Peskov, J. Miyamoto, M. Cortesi, S. Cohen, R. Chechik Weizmann Institute RD51 Paris Oct 08 - Gain: UV vs. X-rays.

Development of a Single Ion Detector for Radiation Track Structure Studies F. Vasi, M. Casiraghi, R. Schulte, V. Bashkirov.

THGEMs: very recent results towards applications in DHCAL & LXe detector readout Weizmann: A. Breskin, R. Chechik, R. Budnik, CERN: V. Peskov Coimbra &

Paul Colas, CEA/Irfu Saclay. E Ionizing particle electrons are separated from ions The electrons diffuse and drift along the an E field Localisation in.

Cryogenic Thick-GEM (THGEM) detectors and their applications Cryogenic Thick-GEM (THGEM) detectors and their applications Affordable instrumentation for.

Thorsten Lux. Charged particles X-ray (UV) Photons Cathode Anode Amplification Provides: xy position Energy (z position) e- CsI coating 2 Gas (Mixture)

Study of the cryogenic THGEM-GPM for the readout of scintillation light from liquid argon Xie Wenqing( 谢文庆 ), Fu Yidong( 付逸冬 ), Li Yulan( 李玉兰 ) Department.

Presented by Samuel DUVAL On behalf of the Xénon group Industry-Academia Matching Event on Micro-Pattern Gaseous Detectors April 2012, Annecy-le-Vieux.

Precision Drift Tube Detectors for High Counting Rates O. Kortner, H. Kroha, F. Legger, R. Richter Max-Planck-Institut für Physik, Munich, Germany A. Engl,

R&D activities on a double phase pure Argon THGEM-TPC A. Badertscher, A. Curioni, L. Knecht, D. Lussi, A. Marchionni, G. Natterer, P. Otiougova, F. Resnati,

Large THGEM sampling elements for DHCAL status report

Thick-GEM sampling element for DHCAL: First beam tests & more

Amos Breskin Weizmann Institute of Science

Study of TGEMs and RETGEMs for the possible ALICE upgrade

MPGD 2015 Concise Summary Amos Breskin.

standard THGEM versus FLOWER

WG1 Task2 New structures, new designs, new geometries

THGEM: Introduction to discussion on UV-detector parameters for RICH

Micro-Pattern Gaseous Detectors

LIQUID Xe DETECTOR FOR CONTRABAND DETECTION

PHOTON DETECTION AND LOCALIZATION WITH THE

Production of a 3D-Printed THGEM Board

E. Erdal(1), L. Arazi(2), A. Breskin(1), S. Shchemelinin(1), A

Presentation transcript:

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Recent Advances in THGEM Detectors M. Cortesi, A. Breskin, R. Chechik, R. Alon, J. Miyamoto Weizmann institute of science, Rehovot, Israel V. Dangendorf Physikalisch Technische Bundesanstalt, Braunschweig, Germany

THGEM Marco Cortesi Weizmann Institute of Science PANIC08Amos Breskin 2008 CERN-LHC-ALICE Rutherford & Geiger Van der Graaf 1968 Charpak

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Micro-pattern gas detectors Scaling down the distance between electrodes : -) Larger signal -) Fast ions collection  high rate capability -) Improved localization accuracy (almost as good as solid state det.) Sauli (1997) Detector already used in various HEP experiments Giomataris (1996)

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Thick-GEM (THGEM) multipliers Manufactured by standard PCB techniques of precise drilling in G-10 (and other materials) and Cu etching. ECONOMIC & ROBUST ! Hole diameter d = mm Distance between holes a = mm Plate thickness t = mm Chechik et al. NIM A535 (2004) 303 1e - in e - out E 0.1 mm rim to prevent discharges Single-electron sensitivity Effective single-photon detection 8ns RMS time resolution Sub-mm position resolution >MHz/mm2 rate capability Cryogenic operation: OK Broad gas & pressure selection

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Gain (single electrons) Example: THGEM photon detector with reflective CsI photocathode. : Gain Single-THGEM: Gain 0.4 mm Reflective PC 0.7 mm 0.3 mm C. Shalem et al. NIM A558 (2006) 475 & NIM A558 (2006) 468 New Result UV

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Higher total gain ( ) >10 3 higher gain at same V TGEM Better stability Double-THGEM multiplier: Gain ns R. Chechik et al. NIM A553(2005)35 Single photoelectrons C. Shalem et al. NIM A558(2006)468 New Result Timing resolution RMS: MIPs & single photon ~ 10 nsec Multi-Photons pulses ~ 1 nsec UV Reflective PC R. Alon et al JINST 3 P11001

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 A VERY FLAT GASEOUS IMAGING DETECTOR 100x100mm 2 THGEM With 2D delay-line readout M. Cortesi et al JINST 2 P09002 Resistive anode (C paint-sprayed on PCB) E Hole E Tran E Ind E Drift Soft X-Ray Localization resolution: 0.7mm FWHM Ar/Ch 4

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 30x30 cm 2 THGEM! Oct. 2008

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Photon detector w reflective CsI PC deposited on the THGEM (e.g. RICH photon detectors) Properties: -) High efficiency for single-photon detection -) Low sensitivity to MIPS background radiation (e.g. in RICH). (same principle as with multi-GEMs for RHIC- PHENIX hadron blind detector) Extensive R&D for upgrade of COMPASS & ALICE RICH e Ref. PC E drift E E E=0 MIP

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 THGEM Muon Chambers CMB FAIR: Muon Chamber Main Requirement: Large Area Detector with a HIGH Rate capability Single electrons Rate capability 10MHz/mm 2 with a GAIN of ~10 4 A possible solution: Simple & Economic!

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 THGEM: sampling elements in Digital Hadron ILC Intl. Linear Collider (ILC): “NEW PHYSICS” needs improved jet-energy resolutions 30%/ √ E Digital Hadron Calorimetry: Different concepts proposed for the active sampling elements THGEM: a new solution proposed by Univ. Arlington (UTA) & Weizmann  Interlaced steel-plates and THGEM multipliers.  Simple, robust, thin, compact, stable, high gain SIMULATION THGEM-based DHCAL

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Applications at cryogenic temperature Medical: LXe Gamma camera 2-phase LXe detectors for rare events neutrino-phys, double-beta decay, Dark-matter… Radio-clean material (CIRLEX) photons THGEM-based photomultipliers M.Gai-UCONN / D.McKinsey-YALE / A.Breskin-WEIZMANN Also: Weizmann/Budker cooperation LXe a possible upgrade for “XENON” DM

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Applications with Neutrons Weizmann/PTB/Soreq Multiplier 1 Multiplier 2 gas B, Li, Gd…converter: thermal neutron detector Fast Neutron radiography n THGEMs Read-out electrodes Neutron - charged particles converter Gy/h mm THGEMs Neutron moderator e.g. Li/PE THGEMs Read-out electrodes THGEMs Read-out electrodes THGEMs Position-Sensitive spectrometer for BNCT gas Fast-neutron radiography

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 n elemental radiography 2D image with 30x30 cm triple-GEM In preparation: double-THGEM Pulsed neutrons + TOF Multiple images at different energies  different absorption cross-sections  radiography of different elements graphite Graphite image

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Single-photon Single-photon imaging. e.g. Ring Imaging Cherenkov (RICH) detectors. Particle Fast Particle tracking at moderate (sub-mm) resolutions + high rates. ILC. TPC (Time Projection Chamber) moderate-resolution readout elements for large-volume rare-event detectors. Sampling elements in calorimetry. Ionization & scintillation recording from Liquid noble-gas detectors, including 2-phase detectors (Dark-Matter, neutrino, Gamma Cam…) X-ray n Moderate-resolution (sub-mm), fast (ns) X-ray and n imaging. Summary Recent review: Breskin et al “A concise review on THGEM detectors” NIMA, online in Science Direct. arXiv: & references therein Robust, economic, large-area radiation imaging detectors FAST, HIGH-RATE, MODERATE LOCALIZATION RESOLUTION

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 MICRO-GROOVE CHAMBER Bellazzini et al NIMA424(99)444 MICROWIRE CHAMBER B. Adeva et al NIMA461(2001)33 MICRO-PIN ARRAY (MIPA) P. Rehak et al TNS NS47(2000)1426 MICRO-PIXEL CHAMBER Ochi et al NIMA471(2001)264 FIELD GRADIENT LATTICE DETECTOR (FGLD) L.Dick et al NIMA535(2004)347 NEW DEVELOPMENTS: MICRO-PATTERN GAS DETECTORS MPGD

THGEM Marco Cortesi Weizmann Institute of Science PANIC08  Cosmic ray Double-THGEM: timing (β/Cosmic Ray) 3mm THGEM Lost Events Cartoon double stage

THGEM Marco Cortesi Weizmann Institute of Science PANIC08 Among current applications: Gy/h mm photons LXe Medical: LXe Gamma camera Pos-sens n-dosimetry - BNCT n-detectors n elemental radiography gas photomultipliers 2-phase LXe detectors for rare events n-phys, bb-decay, Dark-matter… LXe