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WG2 session summary. M . Chefdeville RD51 collaboration meeting 7-10 October 2010, Bari, Italy. Session agenda. Emphasis on operation in argon at low temperature (3 talks) GEM/Micromegas/GridPix MAMMA collaboration presentations (2 talks) Status report and spark study
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WG2 session summary M. Chefdeville RD51 collaboration meeting 7-10 October 2010, Bari, Italy
Session agenda • Emphasis on operation in argon at low temperature (3 talks) • GEM/Micromegas/GridPix • MAMMA collaboration presentations (2 talks) • Status report and spark study • Application with neutrons • GEM for neutron beam diagnostic • High rate application • Micromegas for COMPASS • Proposal of an experiment at a pp collider
The double phase argon LEM-TPC, D. Lussi • Large Electron Multiplier • 1000/500/800 um thickness/diameter/pitch • Two dimensional projective anode • 10x10 cm2 with 3 mm readout pitch • Spark protection and preamplifier • Gas purification system • Cool down phase – filling – recirculation • 1 volume / 48 h • best purity achieved [O2]eq < 0.6 ppb Made @ CERN workshop
The double phase argon LEM-TPC, D. Lussi • Test setup @ CERN
The double phase argon LEM-TPC, D. Lussi • Cosmic tracks • X/Y correlation -> Q sharing close to 1 • Extraction field scan: attachment and time smearing < 1 kV/cm • Landau MPV @ ≠ voltages -> max gas gain ~ 30 • dQ/dx VS time -> e- life-time & [O2]eq • Alternative charge readout: Micromegas (A. Delbart)
First test of Micromegas in double phase liquid Ar, A. Delbart • Robustness test of Bulk Micromegas @ low T • Max. voltage of at decreasing temperature(1300 V@-196° C) • After drying out detector at 80° C for 1 nightgas gain curve was lower than before bath • High pressure gas gain measurement @ Room T • Former Hellaz exp. Chamber • No particular gas purification system • 241 Am alpha source + ORTEC readout of mesh • Gain max of 500 @ 3.5 bar with 50 um micro-Bulk
First test of Micromegas in double phase liquid Ar, A. Delbart • Goal: operation & gas gain measurement with a Bulk-Micromegas • 1D readout with 32 strips (3.1 mm pitch) -> modified PCB (CERN workshop) • 2 bulk done with 128 and 100 um gap
First test of Micromegas in double phase liquid Ar, A. Delbart • Measure gain @ various voltages (10 fC/strip expected for MIP) • Fields of 42, 46, 47 kV/cm, gain of 1,3, 4 • Steep transition from stable to unstable conditions • Signal loss while increasing drift field(250-750 V/cm) not observed 47 kV/cm 42 kV/cm 46 kV/cm
First test of Micromegas in double phase liquid Ar, A. Delbart • The maximum gain is low and may be due to the very high purity of Argon (which is demanded for charge drift in liquid) • Such a low gain could be suitable for neutrino applications but higher gains (>100) are needed for dark matter search • But these are the first tests and further improvements and studies are planned (thinner bulk gaps, micro-bulk, …)
First operation of GridPix low temperature, H. van derGraaf • DARWIN: European R&D project for bi-phase missing mass/energy detectors • With InGrid TPC: • detection of single, individual electronsessential: granularity and the very small source capacitance at pixel input • high (95 %) single electron efficiency • accurate X, Y and Z (timing) precision • potentially: (UV) photon detector
First operation of GridPix low temperature, H. van derGraaf • TimePix proved to work at -100 °C, confirmed at -73 °C, -160 still to be tested • Maximum gas gain of 200 • Might not be a problem with a new TimePix with preamplifier optimized for low temperature application (noise of 20 e- ?) • New collaboration with Rubbia group at CERN • Construct support structure to place GridPix insidethe Cryostat (-186 °C) • First test to check the suitability of detector’selectronical components • Detect scintillation light signal with GridPix • CsI layer on grid 55Fe in pure argon, HVgrid = 350 V P = 1 bar T = -70 C at NLR cryostat gain: ~ 200 !
Characterization of resistive Micromegas for MAMMA, D. Attie • MAMMA: Muon Atlas MicroMegas Activity • High rate application -> avoid sparks or make detector spark-proof • High resistive coating may solve the sparking issue • Test in high intensity beam of detector with different resistive coatings (2009) • Preliminary results • Preparation of next test beam & resistive Bulk characterization • Gain stability and spark topology studies Requirements: High rate capability (≤ 10 kHz.cm-2) Spatial resolution ~100 µm (θ ≤ 45 °) Radiation hardness and good ageing properties Time resolution ~few ns Level1 triggering capability Large surface
Characterization of resistive Micromegas for MAMMA, D. Attie • Strong attenuation of spark current and voltage drop • Spatial resolution of 80 um (1 mm pitch strip) • Low cluster size value 2009 TB preliminary results
Characterization of resistive Micromegas for MAMMA, D. Attie • Setup for the next TB • Increase cluster size with higher diffusion gas (Ar/CF4/iso 95/3/2 -> Ar/iso 98/2) • More detector with smaller strip pitch (0.5 mm) • First characterisation with 55Fe source • Gas gain measurements & energyresolution • Charging up effects & model comparison
Characterization of resistive Micromegas for MAMMA, D. Attie • Sparking study in resistive detectors with an alpha source • Measure voltage drop through a 1 MOhms resistance on 4 adjacent strips and apply threshold
Characterization of resistive Micromegas for MAMMA, D. Attie • In some configuration the resistive coating is able to contain or even suppress the spark signal • Ready for the next beam test at Cern to determine in high rate condition operation the efficiency of the various resistive Micromegas. R17, Joerg like R14, Resistive strips 300 kΩ/□ Standard Bulk
Micromegas progress report, V. Polychronakos • New results with “Joerg” chambers: R11,R12,R13 • Small 100 x 100 mm2 chamber with 100 mm long strips and250 µm strip pitch, 360 strips in total • Characteristics: • Resistive strips connected to the ground • Thin insulating layer between of the resistive and readout strips • AC coupling of signals • Sparks are neutralized through the resistive strips to the ground
Micromegas progress report, V. Polychronakos • Laboratory tests with X-tube and 55Fe quanta
Micromegas progress report, V. Polychronakos • Test in a neutron beam • First plots showed at previous collaboration meeting • New results on spark rate • R11 worked fine in a neutron flux of up to 1.5 x 106 n/cm2 s • Despite sparks, no HV breakdown, no dead time • Measured three Ar:CO2 gas mixtures, 93:7 looks very interesting, with a spark rate almost a factor 5 lower than for 80:20
Micromegas progress report, V. Polychronakos • Test in a high intensity hadron beam • R11, R12, R13, and P3 chambers were tested in +120 GeV pion beamintensities 40 kHz & 5 kHz in two Ar:CO2 mixtures, 85:15 and 93:7 • Main goals: • Study HV and current behavior of resistive and non-resistive chambers in a hadron beam • Measure performance (spatial resolution and efficiency) of resistive chambers • Study performance of long strips (0.4 m & 1m, non-resistive) • A few million of events are being analyzed Event display:Timing at angle 40°
Micromegas progress report, V. Polychronakos MM readout chip designBNL chip features Data Driven System with Peak Amplitude and Time Detection: on-detector zero suppression Neighbour-channel enabling circuitry: high thresholds without losing small amplitudes Able to provide Trigger Primitives for on-detector track finding logic Based on existing chip developed a few years ago for a TPC application Appropriate for a variety of detectors (mMegas, TGC, TPC, GEM, etc.) requiring amplitude and time measurement
Micromegas progress report, V. Polychronakos Example of test of BNL chip with Micromegas Simulation • On-chip zero suppression:only channels that exceed a predefined trigger threshold, plus the two neighbouring ones are analyzed and read out
Micromegas progress report, V. Polychronakos • Next steps • Proceed with full-size prototype (CSC size) • First version is under design • Readout with APV25 chip and RD51 readout system • Test in H6 foreseen in October • Multi-plane full-size prototype design will start this fall • BNL electronicsshouldbeavailable • Could install a test chamber in ATLAS during 2012 shut down
nGEM Detectors for the SPIDERneutron facility, G. Croci Fast neutron beam diagnostic Beam dump 2 layers of CuCrZn alloy interleaved with water Place detector behind to measure neutrons flux • Interaction of deuterium ions of 100 keV with the beam dump: • D + D -> 3He + n(2.45 MeV) • detect any variation of the deuterium beam intensity with1 ns & 20 mm reso. • SPIDER beam divided into 16 groups of 5*16 beamlets of20x22 cm2
nGEM Detectors for the SPIDERneutron facility, G. Croci nGEM detectors • Triple GEM detector • dimensions : 35.2 cm x 20 cm • 3 mm/ 1 mm / 2 mm/ 1 mm gaps • Pads readout with 16*10 = 160 pads of 20 x 22 mm2 • Al or Cu Cathode equipped with a polyethene (CH2) layer used to convert neutrons into protons • Gas mixture Ar/CO2 70%/30% • FE Electronics: CARIOCA(open to other counting chip solution) 60 keV deposited in the gas The Al layer thickness is optimized in order to stop all the protons that are not normally emitted
nGEM Detectors for the SPIDERneutron facility, G. Croci Previous measurements in beam On-going and future tests Gamma test @ Frascati now Neutron TB in November 16 nGEM detectors should be produced in order to equip all the beam dump, total area of about 1.5 m2 2012 The final detector will be HV powered using the new HV GEM module • At Frascati Neutron Generator • Detector divided into 2 halves • One sensitive to 2.5 MeV neutrons (DD reaction) • One sensitive to 14 MeV neutrons(DT reaction) • Readout Anode : 128 readout pads 6x12 cm2 organized in a matrix 16x8
Proposal for a high rate experiment with MPGD readout, D. Kaplan • Fixed target experiment to study CP-violation of hyperons particles • Use Fermilab anti-proton beam and existing apparatus after Tevatron shut down (2011?)
Status report of the Micromegas R&D for COMPASS at Saclay, M. Vandenbroucke Pixelized center for COMPASS APV tunning Parameters Preamplifier feedback current Shaper powering current Shaper feedback current Optimization between noise, amplitude and time occupancy of the APV signals • 40x40 cm2 Bulk Micromegas • 2560 channels read out by APV chips • In COMPASS since end August 2010 with comparable performance with “old” Micromegas
Status report of the Micromegas R&D for COMPASS at Saclay, M. Vandenbroucke PS/T11 test beam, Aug. 2010 Gain measurements Mesh and strip readout Measure that resistive detectors have lower gain Not yet understood Further studies will continue with the October RD51 test beam on SPS • COMPASS/CLAS12 • 6x10 cm2 Bulk detectors • 144 strips with 400 um pitch • Read out by AFTER (T2K) • Investigation of different protection schemes • GEM pre-amplification • Resistive layers • Low energy beam • Study influence of hadron energy • Analysis on-going
Last slide • Thanks to the speakers for their contributions • Thanks you all for your attention