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Micromegas for the Central Tracker. Sébastien Procureur CEA-Saclay. Micromegas and CLAS12. - 3 double layers of cylindrical MM (Barrel). ~ 4 m². - 3 double layers of flat MM ( Forward ). Micromegas CLAS collaboration meeting, 09 /03/2011 S.Procureur. - PowerPoint PPT Presentation
Micromegas for the Central Tracker
Sébastien Procureur CEA-Saclay
Micromegas and CLAS12
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
- 3 double layers of cylindrical MM (Barrel)- 3 double layers of cylindrical MM (Barrel)- 3 double layers of flat MM (Forward)- 3 double layers of flat MM (Forward) ~ 4 m²~ 4 m²
The MM challenges (Cerchi dell'Inferno)
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
“Abandon all hope, you who enter here”
Cylindrical MicromegasMake use of the « bulk » technology (2006)Make use of the « bulk » technology (2006)
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
2 to 4 mm 128 mMini: 4 mm
Mesh
Photoresist border
Photoresist amplification spacer (~300 µm)
PCB with strips
→ → more robustmore robust
→ → PCB can be thinPCB can be thin
Cylindrical MicromegasPerformance compared to thick flat MM using cosmicsPerformance compared to thick flat MM using cosmics
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
→ → similar performance as thick detectorssimilar performance as thick detectors
Thick detector Thin detector
Spatial resolution in 5 TX tiles of Barrel Micromegas are sensitive to the Lorentz angle of drifting electronsX tiles of Barrel Micromegas are sensitive to the Lorentz angle of drifting electrons
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
x = h tanθ = h v B / E
x
h → → minimize h (but less signal)minimize h (but less signal)
→ → use heavier gas (but more sparks)use heavier gas (but more sparks)
→ → increase E field (but lower transparency)increase E field (but lower transparency)
Garfield simulation
→ → ~ 220 µm if ~ 220 µm if can be lowered down to 20° can be lowered down to 20°
Spatial resolution in 5 TTest to validate Garfield simulation with a Micromegas in dvcs magnet (Hall B)Test to validate Garfield simulation with a Micromegas in dvcs magnet (Hall B)
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
Garfield validated, Garfield validated, can be as low as 20° can be as low as 20°
→ → use of a focused UV laser to extract electrons use of a focused UV laser to extract electrons from the drift electrodefrom the drift electrode
P. Konczykowski P. Konczykowski et al.et al., NIM A612 (2010), 274, NIM A612 (2010), 274
Large area detectorsFull size Y prototypes have been built at CERNFull size Y prototypes have been built at CERN
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
→ → doubled area compared to COMPASSdoubled area compared to COMPASS
50x60 cm²
1400 channels→ → CCdetdet ~ 25 nF, C ~ 25 nF, Cstripstrip from 90 to 120 pF (can be reduced) from 90 to 120 pF (can be reduced)
Scan with Fe55 source → → 90% of strips OK (1st proto!)90% of strips OK (1st proto!)
→ → ready to build them at Saclayready to build them at Saclay
ElectronicsThe limited space requires an off-detector electronics → long cablesThe limited space requires an off-detector electronics → long cables
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
→ → Irakli found 70 pF/m (Hitachi)Irakli found 70 pF/m (Hitachi)
→ → initial cables were 160 pF/m (FLEX)initial cables were 160 pF/m (FLEX)
→ → CCcabcab = 105 pF ~ C = 105 pF ~ Cstrip strip
→ → Significant effect on S/B (~50%)Significant effect on S/B (~50%)
→ → Needs 10 V more to be compensatedNeeds 10 V more to be compensated
Electronics - recent developments
0,7
0,8
0,9
1
1,1
1,2
1,3
1,4
1,5
1,6
1,7
1,8
1,9
0 20 40 60 80 100 120 140 160 180 200
Mag
nitu
de A
DC
inpu
t (V)
Input capacitance (pF)
Asic DREAM0: Magnitude versus input capacitance
AGET
modif
Dream: reworked input stage adapted to high detector capacitances up to 200 pF→ ENC of 2200e for 150 ns peaking time→ Expected S/N : 30 – 40 depending on gain
Test bench: Dream carrier board in place & route→ Up to 7 Dreams→ One Dream on a remote board
Firmware: in progress→ Test bench and front-end unit firmware→ Goal: estimate FPGA resources needed
Detector cables: Hitachi 50 pF/m cables expected on March 15th
→ check ability to withstand sparks→ Goal: 40 pF/m cables
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
DREAM and test bench schedule
• February: Dream carrier board place & route started
• End of March
– Submission of Dream
• Backup date: end of April
– Production of the Dream carrier board
• April: Dream carrier board in test
• May: Dream test bench ready
– Final adjustments for firmware and software
• June: packaged Dream ready for tests
– T2-T3 – Dream tests
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
Spark rate studiesActivity started in 2009Activity started in 2009
→ → simulation: try to relate sparks with largesimulation: try to relate sparks with large energy deposits with Geant4 (Gemc)energy deposits with Geant4 (Gemc)
→ → spark condition: Nspark condition: Nelel ~ 10 ~ 1077 (Raether) (Raether)
→ → Quantitatively reproduces (few) existing dataQuantitatively reproduces (few) existing data
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
→ → Explains gas effect & give predictions (bulk)Explains gas effect & give predictions (bulk)
S. Procureur S. Procureur et al.et al., NIM A621 (2010), 177, NIM A621 (2010), 177
Spark rate studies
→ → 6 different detectors in 150 GeV pion beams6 different detectors in 150 GeV pion beams
→ → bulk ~ non-bulkbulk ~ non-bulk
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
S. Procureur S. Procureur et al.et al., submitted to NIM (Feb. 1st 2011), submitted to NIM (Feb. 1st 2011)
Tests at CERN/SPS, October 2009Tests at CERN/SPS, October 2009
→ → Effect of a 1.5 T Effect of a 1.5 T magnetic field magnetic field
→ → 11stst test of a MM+GEM detector (D. Neyret) test of a MM+GEM detector (D. Neyret)
→ → No strong effect of B fieldNo strong effect of B field
→ → 1 week of data1 week of data
Spark rate studies
→ → 1 MM & 1 MM+GEM in FROST setup1 MM & 1 MM+GEM in FROST setup
→ → simulation ~ OKsimulation ~ OK
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
B. Moreno B. Moreno et al.et al., submitted to NIM (Mar. 8th 2011), submitted to NIM (Mar. 8th 2011)
Tests at JLab/Hall B, July 2010Tests at JLab/Hall B, July 2010
→ → Effect of a 5 T // magnetic fieldEffect of a 5 T // magnetic field
→ → 100 with GEM foil100 with GEM foil→ → x10 with 5 T fieldx10 with 5 T field
→ → 2.5 days of data2.5 days of data
Spark rate studies
→ → 12 detectors in 12 detectors in ππ++ or or ππ-- beam beam
→ → peaks in spark rates with peaks in spark rates with ππ++
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
G. Charles G. Charles et al.et al., submitted to NIM (Feb. 25th 2011), submitted to NIM (Feb. 25th 2011)
Tests at CERN/PS, August 2010Tests at CERN/PS, August 2010
→ → beam momentum tunable between 0.2 and 3 GeV/cbeam momentum tunable between 0.2 and 3 GeV/c
→ → confirms GEM effectsconfirms GEM effects
→ → 2 MM+GEM to understand spark rate suppression2 MM+GEM to understand spark rate suppression
→ → 2 weeks of data2 weeks of data
Spark rate – last mysteries
→ → effect of the longitudinal 5 T fieldeffect of the longitudinal 5 T field
→ → strong hint for significant effect of transverse diffusionstrong hint for significant effect of transverse diffusion
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
2 observations cannot be reproduced by the naive simulation2 observations cannot be reproduced by the naive simulation
→ → spark suppression with the MM-GEM detectorsspark suppression with the MM-GEM detectors
→ → explains all effects seen with MM-GEM:explains all effects seen with MM-GEM:
→ → large suppression with moderate GEM gainslarge suppression with moderate GEM gains
→ → effect of trans. diff. only at high GEM gainseffect of trans. diff. only at high GEM gains
→ → change of slope at high GEM gainchange of slope at high GEM gain
new spark condition: critical surface charge densitynew spark condition: critical surface charge density
Integration
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
Forward Tagger with Micromegas?Project to equip the FMT with central pixels for small angle e- detectionProject to equip the FMT with central pixels for small angle e- detection
- add ~ 6k channels to the FMT (electronics?)- add ~ 6k channels to the FMT (electronics?)
- add 2-4 MM layers in front of calo- add 2-4 MM layers in front of calo
Track finding eff > 95% in pFMT
Track finding eff > 95% in pFMT
Very large background due to MoellerVery large background due to Moeller
zz
φφpp
All hitsAll hits Selected hitsSelected hits
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
Schedule
Conclusion
Micromegas CLAS collaboration meeting, 09/03/2011 S.Procureur
Additional slides
Working pointParameter Barrel (Z&Y) Forward Remarks
Drift space 2-3 mm 5 mm
Gas Ar+10%iC4H10 Ne+iC4H10
Fields ratio 5.5-6 50
Mesh Transparency 40% 40%
Electron Transparency
40-45% ~100% Measured @ B=0
Gain (effective) 5000 3000
Detection Efficiency >90% >95% Measured @ B=0(X)
Tracking Efficiency >93% >90% Simulation (tracking)
Detectors / layer 3 1-2
Background noise/ Detector
2 MHz 12 MHz Geant4 estimate
Sparking rate 1/s 0.4/s Geant4 estimate
Space resolution 220&100 µm 80 µm Garfield estimate
Lorentz angle 20° 0° Garfield estimate, validated
