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MSU Activities

MSU Activities. Michael Merkin December, 8, 2005. Silicon Lab @ SINP MSU. Main goals: Silicon detectors design and development, Front-end electronics for silicon detectors 16 year experience on silicon detectors and relation with microelectronic industry 5 scientists

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MSU Activities

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  1. MSU Activities Michael Merkin December, 8, 2005

  2. Silicon Lab @ SINP MSU • Main goals: Silicon detectors design and development, Front-end electronics for silicon detectors • 16 year experience on silicon detectors and relation with microelectronic industry • 5 scientists • 6 engineers (electronics, mechanics) • 2 programmers ( on-line, off-line) • 2 technicians

  3. Silicon Lab @ SINP MSU • SiLab has almost all necessary equipment for detectors’ measurements. • 2 automatic probe stations (RADAR and A4). • 2 manual probe stations.

  4. RADAR Automatic Probe Station

  5. RADAR Automatic Probe Station

  6. A4 Automatic Probe Station

  7. A4 Automatic Probe Station

  8. Manual Probe Station

  9. Manual Probe Station

  10. Silicon Lab @ SINP MSU • Hadron-electron separator @ ZEUS (DESY) • Advanced Thin Ionization Calorimeter (ATIC) - Balloon Experiment • Forward part of D0 (FermiLab) silicon tracker – H-disks • Nose Cone Calorimeter for Phenix experiment at RHIC (BNL)

  11. Silicon Lab @ SINP MSU Main Experiments • SVD-2 – open charm experiment on U-70 at IHEP (Protvino) • AMS • ECAL for Future Linear Collider (TESLA) • CBM (Compressed Baryonic Matter) Experiment at GSI (Darmstadt)

  12. ATIC Experiment

  13. D0 Experiment, FNAL H-disk wedge for D0 Experiment Completed H-disk

  14. TESLA/FLC/ILC Sensors • 4” high resistivity wafers • wafer thickness 525 m • sensor size: 62.0+0.0 -0.1 mm • scribe line: 60 m • active area size: 60.0 • the dead zone width is about 1 mm

  15. TESLA/FLC/ILC Sensors

  16. TESLA/FLC/ILC Sensors

  17. TESLA/FLC/ILC Sensors

  18. Production Status • Total 233 wafers have been developed • Number of good sensors – 130 • Sensor with high FDV - 57 • We had a few minor problems, but might be, it is because of fraction not good wafers.

  19. TESLA/FLC/ILC Sensors

  20. TESLA/FLC/ILC Sensors

  21. PHENIX Forward Calorimeter

  22. PHENIX Forward Calorimeter • Starts at Z - 40 cm • Radial Coverage - 50 cm • Geometrical Depth - 20 cm • Absorber - W • Sampling cells - 22 • Total depth (Rad. length) - ~40 • Expected EM en. Resol. - 20% • Cell size - 1.5*1.5 cm2

  23. PHENIX W-Si Forward Calorimeter

  24. Calorimeter: Sampling cell design • To avoid • draining bulk current into electronics; • loss of electronics whenever channel trips; • and to save space • Thin film technology used to implement rc-chip on interconnect board Sensors carrier board Absorber (W)

  25. Prototype Silicon Wafers For Calorimeter 62 mm 62 mm Si Wafer :4x4 pads of detection (15x15 mm2) 4” High resistive wafer : 5 Kcm Thickness : 500 microns  3 % Tile side : 62.0 + 0.0 - 0.1 mm Guard ring In Silicone ~80 e-h pairs / micron  40000 e- /MiP Capacitance : ~80 pF Leakage current : ~ 5 nA Full depletion bias : <200 V Nominal operating bias : 250 V • ELMA: • Well established technology; • Long production history • Good reputation

  26. Calorimeters: g-p0 identifier Y 500 m RC Test structure mask SVX4 RC SVX4 X

  27. Prototype w/o FEE

  28. Prototype with FEE Boards

  29. Prototype with FEE Boards

  30. Prototype with FEE Boards

  31. Reconstructed Normalized Positron Energy

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