A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs A. Breskin, A. Lyashenko, R. Chechik Weizmann Institute of Science, Rehovot, Israel J.M.F. dos Santos, F.D. Amaro Univ. of Coimbra, Portugal J. F.C.A. Veloso Univ. of Aveiro, Portugal High-gain Gaseous photomultipliers for the visible spectral range Talk dedicated to my friend Georges Charpak Celebrating 85 in March 2009
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs SK 500mm Vacuum PMT Photomultipliers should go flat! Flat, Low cost Bulky, High cost ~11,000 PMTs ~10mm h photocathode Gaseous electron multiplier readout Super Kamiokande NEXT: UNO : 56,650 PMTs Hyper-K : 200,000 PMTs !!! who can pay? induced ring Gaseous PM
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs UV-GPMs used in experiments: ALICE, HADES, COMPASS, J-LAB, PHENIX UV - Gaseous Photomultipliers (GPM) GPM Rev: Chechik & Breskin, NIM A595(2008)116 CERN-ALICE PHENIX Wire-chamber Triple-GEM 400 x 600 mm x 250 mm 2 CRYO: Bondar, 2008 JINST 3 P07001 UV photon e-e- readout electrode CsI photocathode THGEM Double-THGEM NEW! Thick-GEM Talk by Chechik
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Secondary effects in GPMs “open geometry” GPM Main problem: Ions & photons secondary e emission Ion & photon feedback pulses gain & performance limitations PC masked by electrode Much lower photon feedback Lower ion-feedback better performance Hole-multiplier PC h
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Motivation for R&D: large areas flat geometry (1bar gas) operation in magnetic fields sensitivity to single photons fast (ns) high localization accuracy (sub-mm) low cost (dream: few-$/cm 2 ) Visible-sensitive GPMs Rev: Chechik & Breskin NIM A 595 (2008) 116 Sealed Triple-GEM with K-Cs-Sb Previous status: bialkali stable under avalanche gas detectors with coated bialkali Sealed triple-GEM with bialkali high gain only in pulsed-gate mode low aging under avalanche MAIN DIFFICULTY: ION FEEDBACK 70μm 50μm GEM: Gas Electron Multiplier Sauli, NIM A 386(1997)531 Balcerzyk, IEEE Trans. Nucl. Sci. Vol. 50 no. 4 (2003) 847
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Visible-sensitive GPM: Ion-feedback development stable operation of visible sensitive GPMif CsI K-Cs-Sb K-Cs-Sb, Na-K-Sb, Cs-Sb : Current deviates from exponential Max Gain ~ few 100, IBF~10% G~10 5, γ + eff ?, IBF?
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs IBF depends on effective ion-induced electron emission from PCs PCK-Cs-SbNa-K-Sb IonCH 4 + γ + eff (experimental) 0.03± ±0.006 γ + eff (theory) PC Ar/CH 4 (95/5), γ eff + ~0.03, Gain ~ 10 5 IBF < 3.3*10 -4 stable operation of visible sensitive GPMif Lyashenko et al, in preparation backscattering on gas molecules Function of E e- (~7eV) Function of: E ion & PC material ( E ion ~13eV for CH 4 + ) extr ~ 7% in Ar/5%CH 4
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Cascaded-GEM GPMs: high gain but also high ion back-flow Semitransparent GPM Reflective GPM
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs IBF: Ion Back-Flow Fraction IBF: The fraction of avalanche-generated ions back-flowing to the photocathode Challenge: BLOCK IONS WITHOUT AFFECTING ELECTRON COLLECTION Bachman, NIM A438(1999)376 IBF= 5% Breskin, NIM A478(2002)225 IBF= 2-5% Bondar, NIM A496(2003)325 IBF= Edrift 0.5kV/cm, Gain ~10 5 : IBF~ Need another factor of 100!!! IBF
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs operated with ion gating Gaseous detectors with Visible-PC Ion gating NO FEEDBACK ! GATED MULTI-GEM DC: IBF~10 -1 → gain limited to 10 2 Ion gating: IBF~10 -4 → gain ~10 6 Moerman, PhD Thesis, 2005 JINST TH004 Breskin, NIM A553 (2005) But: gating dead-time; needs trigger
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs The Microhole & Strip plate (MHSP) Two multiplication stages on a single, double-sided, foil R&D: Weizmann/Coimbra/Aveiro MHSP: Veloso, Rev. Sci. Inst. A 71 (2000) 237 Maia, NIM A A523(2004) IBF ~ Strips: multiply charges
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Reverse-biased MHSP (R-MHSP) concept Flipped-Reversed-MHSP (F-R-MHSP) Reversed-MHSP (R-MHSP) Can trap its own ions Ions are trapped by negatively biased cathode strips Lyashenko JINST (2006) 1 P10004 Lyashenko JINST (2007) 2 P08004 Roth, NIM A535 (2004) 330 Breskin NIM A553 (2005) 46 Veloso NIM A548 (2005) 375 Can trap only ions from successive stages Strips: collect ions
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Lyashenko 2007 JINST 2 P08004 IBF measured with 100% e-collection efficiency IBF=3*10 Gain=10 5 100 times lower than 3GEMs 1st R-MHSP or F-R-MHSP: ion defocusing (no gain!) Mid GEMs: gain Last MHSP: extra gain & ion blocking BEST ION BLOCKING: “COMPOSITE” CASCADED MULTIPLIERS: IBF=3*10 -4
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs NEW! “COBRA”: GEM-LIKE PATTERNED ION-SUPPRESSING ELECTRODES New ideas for ion blocking IBF=3*10 -6 Gain=10 5 IBF 1000 times lower than with GEMs; best results ever achieved But: 20% photoelectron collection efficiency… TRYING TO IMPROVE!
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Sealed detector Test detector setup Visible-sensitive GPM UHV compatible materials Bi-alkali photocathode cascaded multiplier GEM/MHSP
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Multi-alkali photocathode production (QE nm in vacuum for semi-transparent PC) Hot Indium sealing to UHV setup for photocathode/detector investigations M. Balcerzyk et al., IEEE TNS Vol. 50 no. 4 (2003) 847 D. Moerman, PhD Thesis 2005 JINST TH 004
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs 20% QE 2 μC/mm 2 ion charge on photocathode: only ~ 4 x faster drop compared to thin ST CsI (~8 μ C/mm 2 ) K-Sb-Cs PC ageing in avalanche mode Real conditions: gain=10 5 ; IBF=3* % QE drop 46 5kHz/mm 2 ph. same conditions with a MWPC (IBF=1) 3000 times shorter lifetime: ~5 days! Breskin NIM A553 (2005) 46 Typical QE of bi-alkali PC produced in our lab vacuum K-Cs-Sb Na-K-Sb Lyashenko et al, in preparation
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Continuous operation of F-R-MHSP/GEM/MHSP with K-Cs-Sb photocathode with K-Cs-Sb photocathode Gain ~10 5 at full photoelectron collection efficiency First evidence of continuous high gain operation of visible-sensitive GPM K-Cs-Sb CsI 10 5
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Visible-sensitive GPM features Single photon sensitivity No ion-feedback Fast ns pulses 19 ns 100 photoelectrons Lyashenko et al, JINST, in preparation
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs fresh PC after 14 hours of operation photocathode stability inside UHV preparation chamber Rate: 12kHz/mm 2 photons Gain: 10 5 Total anode charge ~125μC PC is stable in gas in the large vacuum chamber Expected even better stability for sealed devices Kapton glass? Ceramic? Other? gas Lyashenko et al, JINST, in preparation
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs BACKSCATTERING IN GAS: EFFECTIVE QE Coelho, NIMA 581(2007)190 Breskin, NIM A483 (2002) 670 Dashed-lines are simulation Noble gases Divergence due to scintillation CsI QE eff = QE x transmission (e - extraction efficiency into gas) TRANSMISSIONTRANSMISSION TRANSMISSIONTRANSMISSION transmission Back-scattering h GAS PC
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Photoelectron transmission from K-Cs-Sb as a function of E-field & photon wavelengths 700 Torr Methane 700 Torr Ar/CH4 (95/5) Higher effective QE at longer WL’s NEW Lyashenko et al, in preparation QE eff = QE x transmission (e - extraction efficiency into gas)
A. BreskinTIPP09 Tsukuba VISIBLE-SENSITIVE GAS-PMs Summary Cascaded Patterned Hole Multipliers (MHSP/GEM) RECORD in ion blocking in gaseous detectors, crucial in GPMs IBF~ with full photoelectron collection efficiency! Further improvements in progress (other patterned electrodes) NEW : Stable visible-sensitive GPM DC-mode operation at 10 5 Photocathodes “Reasonable” effective QE in 1 bar gas 400nm); can be improved (gas/geometry) Potential applications Atmospheric-pressure large-area photon detectors! Potential applications in Particle Physics, Astroparticle, Medical, NDT, etc Suitable for cryogenic operation (UV GPMs OK) SCIENTIFICALLY FEASABLE BUT: INDUSTRIAL PROJECT!