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MUON TRACKER FOR CBM experiment

MUON TRACKER FOR CBM experiment. Detector Choice. Murthy S. Ganti, VEC Centre. Highest hit density expected at various muon stations (URQMD, central). Effective rate ~10MHz/Cm 2. Comparison of detectors. Both GEM & MICROMEGAS are suitable for high rate applications.

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MUON TRACKER FOR CBM experiment

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  1. MUON TRACKER FOR CBM experiment Detector Choice Murthy S. Ganti, VEC Centre

  2. Highest hit density expected at various muon stations (URQMD, central) Effective rate ~10MHz/Cm2

  3. Comparison of detectors.. Both GEM & MICROMEGAS are suitable for high rate applications

  4. GasElectronMultiplier - GEM Manufactured with technology developed at CERN 100-150 µm Typical geometry: 5 µm Cu on 50 µm Kapton 70 µm holes at 140 mm pitch

  5. GEM.. Thin metal-coated polyimide foil chemically etched to form high density of holes. On application of a voltage gradient, electrons released on the top side drift into the hole, multiply in avalanche and transfer to the other side. Proportional gains above 103 are obtained in most common gases. F. Sauli, Nucl. Instrum. Methods A386(1997)531

  6. Multi GEM configurations..

  7. Single-Double-Triple GEM Multiple structures provide equal gain at lower voltage The discharge probability on exposure to a particles is strongly reduced For a gain of 8000 (required for full efficiency on minimum ionizing tracks) in the TGEM the discharge probability is not measurable. S. Bachmann et al, Nucl. Instr. and Meth. A479 (2002) 294

  8. GEM..

  9. GEM..

  10. GEM..

  11. Narrow charge distribution problem..

  12. GEM… • High (100 mm) pitch small pad response function • No ExB effects better resolution • Direct electron signal no losses • Efficient ion collection • Easy to build • Robust to aging insensitive to LHC backgrounds • Multi-stage structureslarge gains (103-104) • Low mass construction no wire frames

  13. Issues of implementing GEM in Large area detectors.. • Only a few sources of supply • Large area GEM foils are difficult to fabricate. Small foils leave large dead areas in the tracking plane • Single stage GEM gain is low • Expensive (relative)

  14. MICROMEGAS.. High (50 mm) pitch small pad response function No ExB effects better resolution Direct electron signal no losses Funnel effect very efficient ion collection Electron amplification independent of the gap to first order promising dE/dx Easy to build dead zones potentially small Robust to aging insensitive to LHC backgrounds Good electro-mechanical stability large gains (103 -104) Low mass construction no wire frames

  15. MICROMEGAS – discharges .. • Detailed investigations have shown that the rate capability of the gaseous detector strongly • depends of the type of the incident particle beam and the nature of the gas mixture. A test in a • high energy muon beam at a rate of 108/s showed that Micromegas can cope with very high flux of • these particles. • However, an undesirable effect has been observed when the incident beam is composed by high- • energy hadrons: a discharge rate proportional to the incident hadron rate. It is believed that • sparks are triggered by large charge deposits in the drift space from recoil nuclei produced by • charged particles, especially hadrons, traversing the detector. In the case of muons the • corresponding cross section is several orders of magnitudes lower, therefore the probability to • induce sparks is negligible. • Several investigations in the PS beam have shown a continuous decrease of the discharge • probability from heavy to light gas fillings. The most promising are Helium mixtures and the effect • is illustrated in Fig.1. With a gas mixture of He + 10% Isobutane the discharge probability • decreases with the cathode mesh voltage of the detector; at 420 Volts, the lowest required • voltage for full detection efficiency, the probability reaches a value (<108) that is suitable for safe • operation of the detector in high particle environment.

  16. Mesh Choice for MICROMEGAS.. Copper with integrated polyimide pillars (by etching technology Electroformed mesh SS woven mesh Advantages of Woven mesh 1. they exist in rolls of 4 m x 40 m and are quite inexpensive, 2. they are commonly produced by several companies over the world, 3. there are many metals available: Fe, Cu, Ti, Ni, Au, 4. they are more robust for stretching and handling.

  17. Mass produced MICROMEGAS

  18. Double mesh MICROMEGAS • Protection of Front end electronics from discharges • Cathode and readout pad plane are separated S. Kane et al./NIM A 505(2003)215-218 Purdue University

  19. MICROMEGAS : Some practical questions • Choice of wire mesh : Woven vs. electro-formed vs. etched copper clad kapton • Bulk MICROMEGAS – pillars of photo resist. Also other spacers like fish line • How to optimize ion backflow? Practical limitations of mesh aperture(LPI) • Minimizing discharges due to heavily ionizing particles ( nuclear recoils) • Choice of gas mixtures • Muon tracking at high rates: how to widen pad response function? • Need of resistive coating ( Cermet, graphite) • Other readout schemes : Second anode mesh and a separate readout pad plane • Practical construction : • How to paste mesh to frame? how to protect mesh edges? • How much Minimum frame width? • How to tap HV connection? • Frame material, rigidity • Mesh sag due to temperature fluctuations • Invar mesh (shadow mask of CRTs)? • Effect of pad ridges on field uniformity

  20. Thick GEM.. Worth investigating further for CBM Muon Tracker..

  21. Design concepts.. • Wheel type design of planes with 8 sector type chambers in each plane • Each sector with a single woven mesh supported on insulating pillars or THGEM • Readout pad granularity to vary from 3mm to 7mm pads radially in 3 zones - to keep occupancy within 10% level • (needs further optimization study)

  22. Lot of Work to do!

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