Presentation is loading. Please wait.

Presentation is loading. Please wait.

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.

Published byFelicity Gardner Modified over 9 years ago

Similar presentations

Presentation on theme: "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."— Presentation transcript:

1 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 [1,3], M. L. Rappaport [1], S. Shchemelinin [1], D. Vartsky [1,4], J. M. F. dos Santos [2] and A. Breskin [1] [1] Weizmann Institute of Science [2] Coimbra University, Coimbra, Portugal [3] NRC Negev, Israel [4] On leave from Soreq NRC, Israel 7 th Symposium on Large TPCs for Low-Energy Rare-Event Detection, Paris November 14, 2014

2 CRYOGENIC GASEOUS PHOTOMULTIPLIERS 2 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

3 Dual-phase LXe TPC with Gaseous Photo-Multipliers (GPMs) LXe PMTs Potentially low-cost (in-house module assembly) 4 π coverage (improved sensitivity to low-mass WIMPs ) 90-95% filling factor (compared to 50-60% with PMTs) ~10-fold better position resolution through smaller pixels  better calibration and background discrimination? Potentially low-cost (in-house module assembly) 4 π coverage (improved sensitivity to low-mass WIMPs ) 90-95% filling factor (compared to 50-60% with PMTs) ~10-fold better position resolution through smaller pixels  better calibration and background discrimination? 3 GPMs L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

4 0.4 mm E Thick Gas Electron Multiplier (THGEM) ~ 10-fold expanded GEM Chechik VIENNA 2004 Thickness 0.4-1mm drilled etched SIMPLE, ROBUST, LARGE-AREA Printed Circuit-Board TechnologyAmos THGEM 1 e - in ~10 3 e - out 4 Robust, if discharge no damage Can be cascaded for high gain Effective single-photon detection when coupled to a photocathode Few-ns RMS time resolution Sub-mm position resolution Can be made of radio-pure materials Cryogenic operation: OK Broad pressure range: 1mbar - few bar L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

5 5 Top array GPM – triple THGEM with reflective CsI Xe Ne/CH 4 Pixel readout Reflective Cesium Iodide (CsI) photocathode mesh UV window ~10 mm L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

6 Wall GPM – semitransparent + reflective CsI UV window Semitransparent CsI Pixel readout Ne/CH 4 ~10 mm Xe 6 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014 Reflective CsI

7 WIS Liquid Xenon (WILiX) facility: playground for detector R&D 7 WILiX schematic view LXe TPC GPM Smaller cryo-GPM see: Duval 2011 JINST 6 P04007 4” triple-THGEM GPM CsI coated L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

8 241 Am LXe GXe CsI PMT Ne/CH 4 quartz anode gate First-ever demonstration of S1 & S2 recording by GPM coupled to dual-phase LXe TPC ! 8 α 1 kV/cm 10 kV/cm Detect single photons AND massive S2 signals! October 24 2014 PMT GPM S1 S2 S1 S2 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

9 Gain and stability ~1∙10 5 enough for >90% single-PE detection above noise Gain reproducible to 10-15% over many days NO SPARKS at 1.1∙10 5 for alpha S1+S2 with ~100-fold larger cosmics S2! (discharge probability < 3∙10 -6 ) 9 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

10 Energy resolution 10 α S1 ~30 PEs α S2 ~5000 PEs 60 keV γ α & γ coincidence σ /E = 11% σ /E = 8.7% Ne/CH 4 (5%) 514 torr, 180K Gain 1.1∙10 5 S2 energy resolution similar to XENON100 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

11 Time resolution But with only ~1.2 ns jitter! GPM signal lags by ~200 ns after PMT PMT GPM (preamp out) 11 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

12 Overall QE and expected PDE (top array) QE eff = QE CsI × A eff × ε ext × ε col QE eff : probability to get a photoelectron into a THGEM hole per photon passing the window QE CsI : intrinsic CsI QE (at LXe temp) A eff : fraction of detector area covered with CsI ε ext : extraction efficiency – the probability that a photoelectron will not be backscattered to the CsI ε col : collection efficiency – the probability that an extracted photoelectron will be pulled to a THGEM hole 12 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

13 13 ε col QE CsI A eff Now 0.77 Can be optimized to >0.85 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014 ε ext

14 QE/PDE of top GPM array - bottom (optimistic) line Including window transmission (0.9) and probability for signal above noise ( ~ 0.95) we expect PDE≈0.15 With a filling factor of 0.9-0.95 the overall PDE is expected to be ~ 0.14 PMTs: for QE=0.36, collection efficiency 0.9 and filling factor 0.5  PDE = 0.16 For wall GPM we expect PDE > 0.2 14 QE eff = QE CsI × A eff × ε ext × ε col ~ 0.25 × 0.85 × 0.85 × 1 = 0.18 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

15 Light Yield with 4 π coverage (wall GPM) DARWIN-like 2m LXe TPC with wall GPMs & 90% transparent field cage Top & bottom arrays: PMTs (QE=36%, CE=90%, filling factor=55%), or GPMs with equivalent overall PDE; XENON1t-like meshes 15 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

16 LIQUID HOLE MULTIPLIERS 16Lior Arazi, IEEE2014 UV detectors workshop, Seattle, WA USA, Nov 14 2014

17 BIGGER IS BETTER? S2/S1 discrimination in XENON100 and LUX – fantastic! Will it work on a few-meter diameter TPC? Grids and liquid surface must be parallel everywhere at all times Concerns: tilt, ripples, grid deformation, level variations with conditions  loss of S 2 resolution  loss of discrimination power! 17 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

18 Can one have S 1 +S 2 in single phase liquid- only TPC? 18 GPMs 4  geometry with immersed GPMs LXe level K. Giboni 2011 2014 JINST 9 C02021, 2014 JINST 9 P12007 Recent alpha-induced scintillation S1 and S2 electroluminescence signals recorded from a 10 micron diameter wire in LXe. E. Aprile et al; 2014 JINST 9 P11012 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

19 Can we generate S2 in the holes of an immersed THGEM? 19 THGEM Cathode Mesh Arazi et al 2013 JINST 8 C12004 YES WE CAN! L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

20 Too good to be true? Photon yield: ~600 photons/e in THGEM hole at ~30 kV/cm S2 onset: few kV/cm Photon yield: ~600 photons/e in THGEM hole at ~30 kV/cm S2 onset: few kV/cm 20 S2 spectrum Arazi et al 2013 JINST 8 C12004 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

21 Our present understanding: a “Bubble Chamber” Hypothesis: S2 produced in gas bubbles trapped under the THGEM S2 signals already at few kV/cm (as in Xe gas) S2 responds to pressure: – Disappears after step increase in pressure (bubbles collapse) – Reappears when decreasing pressure (bubbles form again) 21 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

22 Near future : controlled bubbling by carefully-adjusted heating  high resolution Bubbles formation 22 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

23 S2 generation in bubbles is surprisingly steady Stability + controlled effect + resolution + low-field operation  should be exploited towards single-phase noble-liquid DM detectors! Repeatable S2 yields over many weeks 19/6 – 26/8 2014 Several tens of photons/e- @ 3kV Energy resolution with non- spectroscopic alpha source Resolution ~ 12% Getting close to XENON100 with PMTs Oct. 2014 23 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

24 Proposed Implementation in single-phase TPC THGEM top coated with CsI Resistive wires underneath, to form bubbles in controlled way S1 photoelectrons & S2 electrons focused into holes, inducing electroluminescence in bubbles If THGEM field too low – replace by GEM, or GEM+CsI followed by THGEM 24 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

25 Maybe something like this? 25 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

26 Summary Future large scale dark matter experiments call for new solutions Gaseous detectors raison d’être: affordable large-area coverage 4 π coverage by GPMs  large improvement in sensitivity for low-mass WIMPs Top-array GPMs will have 10-fold better position resolution  better calibration, background estimation and rejection? In-house assembly  significant reduction in cost compared to PMTs First results with 4” GPM (top array): large dynamic range, good stability, energy and temporal resolution; overall PDE close to PMTs R&D on wall GPM underway LHMs: for now a curiosity, but may open new options for multi-ton experiments 26 L. Arazi, 7 th Symp. on Large TPCs, Paris, Dec 17 2014

Download ppt "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."

Similar presentations

T. Lux. 13/12/2012 2 Charged particles X-ray (UV) Photons Cathode Anode Amplification Provides: xy position Energy (z position) e- CsI coating.

T. Lux. 13/12/ Charged particles X-ray (UV) Photons Cathode Anode Amplification Provides: xy position Energy (z position) e- CsI coating.
1 Aaron Manalaysay Physik-Institut der Universität Zürich CHIPP 2008 Workshop on Detector R&D June 12, 2008 R&D of Liquid Xenon TPCs for Dark Matter Searches.

1 Aaron Manalaysay Physik-Institut der Universität Zürich CHIPP 2008 Workshop on Detector R&D June 12, 2008 R&D of Liquid Xenon TPCs for Dark Matter Searches.
First observation of electroluminescence in liquid xenon within THGEM holes: towards novel Liquid Hole-Multipliers L. Arazi, A. Breskin, A. Coimbra*,

First observation of electroluminescence in liquid xenon within THGEM holes: towards novel Liquid Hole-Multipliers L. Arazi, A. Breskin, A. Coimbra*,
Hiroyuki Sekiya Jul. 31 st 2008, Philadelphia, ICHEP2008 Development of Gaseous Photomultiplier with GEM/μPIC Hiroyuki Sekiya ICRR, University of Tokyo.

Hiroyuki Sekiya Jul. 31 st 2008, Philadelphia, ICHEP2008 Development of Gaseous Photomultiplier with GEM/μPIC Hiroyuki Sekiya ICRR, University of Tokyo.
R&D on Astroparticles Detectors (Activity on CSN5 2000-2003)

R&D on Astroparticles Detectors (Activity on CSN )
Gas Detector Developments Jin Li. Liquid Xenon case Liquid Xenon can be considered as a gaseous xenon of 520 atm. K.Masuda, S. Takasu, T.Doke et al. (Doke.

Gas Detector Developments Jin Li. Liquid Xenon case Liquid Xenon can be considered as a gaseous xenon of 520 atm. K.Masuda, S. Takasu, T.Doke et al. (Doke.
Dark Matter Searches with Dual-Phase Noble Liquid Detectors Imperial HEP 1st Year Talks ‒ Evidence and Motivation ‒ Dual-phase Noble Liquid Detectors ‒

Dark Matter Searches with Dual-Phase Noble Liquid Detectors Imperial HEP 1st Year Talks ‒ Evidence and Motivation ‒ Dual-phase Noble Liquid Detectors ‒
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs A. Breskin, A. Lyashenko, R. Chechik Weizmann Institute of Science, Rehovot, Israel J.M.F. dos Santos,

A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs A. Breskin, A. Lyashenko, R. Chechik Weizmann Institute of Science, Rehovot, Israel J.M.F. dos Santos,
New Readout Methods for LAr detectors P. Otyugova 20.10.2006 ETH Zurich, Telichenphysik CHIPP Workshop on Neutrino physics.

New Readout Methods for LAr detectors P. Otyugova ETH Zurich, Telichenphysik CHIPP Workshop on Neutrino physics.
The XENON Project A 1 tonne Liquid Xenon experiment for a sensitive Dark Matter Search Elena Aprile Columbia University.

The XENON Project A 1 tonne Liquid Xenon experiment for a sensitive Dark Matter Search Elena Aprile Columbia University.
1 Detectors RIT Course Number 1051-465 Lecture Single Element Detectors.

1 Detectors RIT Course Number Lecture Single Element Detectors.
The UC Simulation of Picosecond Detectors Pico-Sec Timing Hardware Workshop November 18, 2005 Timothy Credo.

The UC Simulation of Picosecond Detectors Pico-Sec Timing Hardware Workshop November 18, 2005 Timothy Credo.
PANDAX Results and Outlook

PANDAX Results and Outlook
A. Lyashenko Alkali-antimonide PCs for GPMPC workshop, Chicago 09 Alkali-antimonide Photocathodes for Gas- Avalanche Photomultipliers Recent review on.

A. Lyashenko Alkali-antimonide PCs for GPMPC workshop, Chicago 09 Alkali-antimonide Photocathodes for Gas- Avalanche Photomultipliers Recent review on.
J.T. White Texas A&M University SIGN (Scintillation and Ionization in Gaseous Neon) A WIMP Detector based on Gaseous Neon The Future of Dark Matter Detection.

J.T. White Texas A&M University SIGN (Scintillation and Ionization in Gaseous Neon) A WIMP Detector based on Gaseous Neon The Future of Dark Matter Detection.
Proportional Light in a Dual Phase Xenon Chamber

Proportional Light in a Dual Phase Xenon Chamber
Detectors for Tomorrow and After Tomorrow… Amos Breskin Radiation Detection Physics Group Weizmann Institute 1 Amos Breskin.

Detectors for Tomorrow and After Tomorrow… Amos Breskin Radiation Detection Physics Group Weizmann Institute 1 Amos Breskin.
C.Shalem et al, IEEE 2004, Rome, October 18 R. Chechik et al. ________________RICH2004_____________ Playa del Carmen, Mexico 1 Thick GEM-like multipliers:

C.Shalem et al, IEEE 2004, Rome, October 18 R. Chechik et al. ________________RICH2004_____________ Playa del Carmen, Mexico 1 Thick GEM-like multipliers:
ZEPLIN II Status & ZEPLIN IV Muzaffer Atac David Cline Youngho Seo Franco Sergiampietri Hanguo Wang ULCA ZonEd Proportional scintillation in LIquid Noble.

ZEPLIN II Status & ZEPLIN IV Muzaffer Atac David Cline Youngho Seo Franco Sergiampietri Hanguo Wang ULCA ZonEd Proportional scintillation in LIquid Noble.
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. Breskin RD51 Amsterdam 4/08 ION BLOCKING & visible-sensitive gas-PMs Efficient ion blocking in gaseous detectors and its application to visible-sensitive.

Similar presentations

Ads by Google