1 / 49

Johann M. Heuser CBM Collaboration Meeting GSI, 15 April 2010

Status of the CBM Silicon Tracking System. Johann M. Heuser CBM Collaboration Meeting GSI, 15 April 2010. 13 contributions from STS team. covering simulations, beam test, detector tests, radiation hardness, demonstrator module, ladder + station engineering, FEE. STS Workgroup.

kerem
Download Presentation

Johann M. Heuser CBM Collaboration Meeting GSI, 15 April 2010

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Status of the CBM Silicon Tracking System Johann M. Heuser CBM Collaboration Meeting GSI, 15 April 2010 J.M. Heuser − Status of the Silicon Tracking System

  2. 13 contributions from STS team covering simulations, beam test, detector tests, radiation hardness, demonstrator module, ladder + station engineering, FEE J.M. Heuser − Status of the Silicon Tracking System

  3. STS Workgroup J.M. Heuser − Status of the Silicon Tracking System

  4. J.M. Heuser − Status of the Silicon Tracking System

  5. STS stations • area, 8 stations: 3.2 m2 • number of sensors: 1068188 sensors, 2 cm × 6 cm 166 sensors, 4 cm × 6 cm 714 sensors, 6 cm × 6 cm • number of sectors: 756 • number of r/o channels: 1.5  106 • number of FE chips: 1.2  104 J.M. Heuser − Status of the Silicon Tracking System

  6. Engineering of STS modules & stations Y. Murin CBM-MPD STS Consortium J.M. Heuser − Status of the Silicon Tracking System

  7. STS – mechanical support Building on technology developed for the ALICE Strip Tracker Consortium - S. Igolkin, StPbU front view of a (half)-station ALICE ITS carbon fiber structure module front top view of a station J.M. Heuser − Status of the Silicon Tracking System

  8. STS assembly details attaching sensors to carbon fibre support J.M. Heuser − Status of the Silicon Tracking System

  9. STS ladder assembly J.M. Heuser − Status of the Silicon Tracking System

  10. STS ladder mockup J.M. Heuser − Status of the Silicon Tracking System

  11. Development of tracking modules tab-bonding of cables to detectors and front-end board Microstrip sensors double sided, CBM01/CBM03 Readout cables * 4-layer* Al-14 m on Kapton-10 m * Shield + spacer layer * 1024 lines, 100-120 µm pitch* up to 60 cm long Front-end board bump-bonded low-power FE chip on a high-density circuit J.M. Heuser − Status of the Silicon Tracking System

  12. Module demonstrators 1-b' J.M. Heuser − Status of the Silicon Tracking System

  13. we have: work hypothesis of STS layout emerging engineering solutions on ladder and station construction beginning prototype work we need: to consolidate the concept build proof-of-principle ladder in 2011-2012 matching components timely availability of components for this work J.M. Heuser − Status of the Silicon Tracking System

  14. STS station layout and simulation of the hit recognition performance 14 A. Kotynia • 1024 strips per sensor; • 15° stereo angle; • 60 µm strippitch; J.M. Heuser − Status of the Silicon Tracking System • Sensors: • 6 cm wide; • 2-6 cm high;

  15. Complete chain of physical processes caused by charged particle traversing the detector Magnetic field influences collection of the charge on the strips 15 Realistic STS Digitizer • |B| = 1T • Holes: • = 1.5° Dx = 8mm Electrons • = 7.5° Dx = 40mm • Particle position in the sensor is obtained by using Center Of Gravity algorithm: • Random noise is added according to a Gaussian distribution with standard deviation as an equivalent noise charge of the detector system J.M. Heuser − Status of the Silicon Tracking System

  16. 16 STS Digitizer – collected charge per strip J.M. Heuser − Status of the Silicon Tracking System

  17. 17 Hit Finding Efficiency large incidence angle J.M. Heuser − Status of the Silicon Tracking System

  18. Channel dead time simulations For minimum bias Au+Au collision at 25AGeV channel occcupancy: J.M. Heuser − Status of the Silicon Tracking System

  19. 19 19 ADC resolution J.M. Heuser − Status of the Silicon Tracking System

  20. we have: realistic model of the STS various varations to it insight in effects on the hit finding efficiency and creation of data volume we need: to further optimize the overall system station layout use the reconstructed hits or hit channels efficiently in the tracking (interface optimization, new stations, ...) overall performance counts J.M. Heuser − Status of the Silicon Tracking System

  21. Performance test of STS demonstrators A. Lymanets 15th CBM collaboration meeting, April 12th, 2010 J.M. Heuser − Status of the Silicon Tracking System

  22. FEB rev. B: • Every second channel bondable. • Still good for lab tests for timing studies or • ADC response (without clustering). • FEB rev. C: • All channels are usable • But thermal stability becomes an issue. • Detector-FEB cable: • Turns out to work if shielded properly. • Detectors of CBM01 and CBM02 type • “behave” similarly (bad), poor charge • collection at n-sides. • FEB 4nx: • Cooling plates improve thermal stability • Problems with surviving potential of the chips • on board. • Beam time : vastly different count rates • in different stations caused by the beam. J.M. Heuser − Status of the Silicon Tracking System

  23. Energy calibration with 241Am Using 300 μm pitch detector => no significant charge sharing Energy gain = 110.6 e-/ADC cnt + one can obtain pedestal energy (not necessarily zero) Noise 460 e- @ 6 pF J.M. Heuser − Status of the Silicon Tracking System

  24. Calibration line Energy calibration is obtained, but extrapolated pedestal amplitude is ~3 kElectrons. Possible reasons: non-linearity, bias due to peak detector. J.M. Heuser − Status of the Silicon Tracking System

  25. n-XYTER chip Power lines current Test channel Channel 0 Output pads Input pads Channel 127 current Power lines J.M. Heuser − Status of the Silicon Tracking System

  26. Pedestal profile over channels Crosstalk problem digital crosstalk – on the chip, not just directly between channels • Pedestal “sag” is observed with maximum in channel #64 • To be addressed in the upcoming engineering run done in Heidelberg Univ. (H. K. Soltveit) J.M. Heuser − Status of the Silicon Tracking System

  27. we have: experience with the first complete system chains developed lots of tools but also destroyed equipment we need: more objects, material, experienced fellows built new tracking modules overcome technology problems (e.g. PCBs at cutting edge designs) thorough long-term tests J.M. Heuser − Status of the Silicon Tracking System

  28. Status of Front End Electronics: n-XYTER PCBs & Power Supply V. Kleipa J.M. Heuser − Status of the Silicon Tracking System

  29. Modifications w.r.t. FEB_C: Increased NXYTER bond pitch 0.3V drop LDOs used Separated supply regulators PT100 sensor out Alternative connector for separated LVDs and common mode signals Testpoints New power connector I2C and SPI spike filter I2C reads now: Temperature Current Testchannels Slow, Fast I2C RW: Serial EEprom for data storage N-XYTER FEB rev. D 20 specimen under construction wire-bonding: C. Simons J.M. Heuser − Status of the Silicon Tracking System

  30. Cooling Block for FEB_B, FEB_C and FEB_D Design by Carmen Simons n-XYTER PCB Cooling Plate C. Simons J.M. Heuser − Status of the Silicon Tracking System

  31. Input pitch 100um PCB size 65mm x 80mm Cooling of 14W power with bottom copper or Al plate ADC device on bottom side Ext. power supply regulation Open task: Staggered NXYTER bonds to one layer input fan Data output connection n-XYTER Demonstrator r/o board J.M. Heuser − Status of the Silicon Tracking System

  32. FEE boards are critical for system studies we have: hopefully now a reasonably stable board (rev. D) we need: to move from 1-chip general purpose board (n-XYTER) to intermediate 4-chip board for ladder tests (n-XYTER) to develop a concept and build a prototype of the 8-chip board (STS-XYTER) to do this: strengthen the team J.M. Heuser − Status of the Silicon Tracking System

  33. Development of microstrip detectors J. Heuser J.M. Heuser − Status of the Silicon Tracking System

  34. CBM02 (2008) CBM03 (2010) CBM01 (2007) (parallel: ISTC01) GSI-CiS Erfurt CBM04 (2010) close-up of a corner of CBM01 J.M. Heuser − Status of the Silicon Tracking System

  35. Close-up of a corner of CBM03 J.M. Heuser − Status of the Silicon Tracking System

  36. we have: essentially one vendor/production partner (CiS) used CBM01 and CBM02 for prototyping work indications that the charge collection is not fully efficient and understood set up framework for TCAD simulations we need: to verify the charge collection properties overcome stability issues to set up a systematic characterization, new material coming (CBM03, CBM04) systematic irradiation studies J.M. Heuser − Status of the Silicon Tracking System

  37. Development of radhard microstrip detectors S. Chatterji J.M. Heuser − Status of the Silicon Tracking System

  38. 3D strip detector simulation model • 3-D TCAD simulation tools “SYNOPSYS” • Sub packages • Sentaurus • Inspect • Tecplot • SPICE (Mixed Mode) X-Y plane of the 3D grid. One can see there is a stereo angle on either side of 7.50. J.M. Heuser − Status of the Silicon Tracking System

  39. Some Static Characteristics • CTotal = Cback+2*Cint • ENC αCTotal • Optimization needed to maximize breakdown voltage & minimize ENC J.M. Heuser − Status of the Silicon Tracking System

  40. Optimizations of the detector design strip pitch and width strip insulation J.M. Heuser − Status of the Silicon Tracking System

  41. Type Energy (eV) Trap σe (cm2) σh (cm2) η (cm-1) Acceptor Ec-0.42 VV 2.0*10-15 2.0*10-14 1.613 Acceptor Ec-0.46 VVV 5.0*10-15 5.0*10-14 0.9 Donor Ev+0.36 CiOi 2.5*10-14 2.5*10-15 0.9 Impact of Radiation Damage • VBD↑ with fluence • Current ↑ by 3 orders • Rint ↓ with fluence • Detailed study needed J.M. Heuser − Status of the Silicon Tracking System

  42. Full system simulation transient signal behavior in the detector and in the readout cable J.M. Heuser − Status of the Silicon Tracking System

  43. Beam pipe options in STS S. Belogurov J.M. Heuser − Status of the Silicon Tracking System

  44. Be: 4 LHC experiments, Belle, Cleo, CDF etc. 0.3 - 0.5 mm typical thickness Al: HERAb 0.3 mm with stiffening ribs. Information availabe, seems reproducible Relevant background for window: LHCb VELO (Ø800 mm 2 mm Al alloy), machined from a forged billet together with the bellow. SF for the LHCb Be beam pipe is 4-6, for window ~ 3 SF for the HERAb beampipe is ~2 J.M. Heuser − Status of the Silicon Tracking System

  45. Studied configurations “Ideal ” configurations. Effects: cylinder-cone; Be-Al. Al: window – scaling from VELO, cone – “simple” manufacturing. Remarks. 1) 0.3 mm Al = 0.5 mm Be 2) Competition works: JSC “Kompozit” started to think about 0.4 mm Be pipe  “Realistic” configurations. Effects of bellows, width of “Tube”. 1.6º configuration fits to ladders of S. Igolkin without cutting the central rib. Any configuration has a weld 1x10 mm J.M. Heuser − Status of the Silicon Tracking System

  46. Results for UrQMD central events at 25 AGeV Range distribution window welding J.M. Heuser − Status of the Silicon Tracking System

  47. Results for UrQMD central events at 25 AGeV Comparison of Al and Be cones done as well for tubes No pipe  Al tube will do ? System engineering, workshop in Fall 2010? /c No pipe Lambda  p pi- K0  pi+ pi- /c J.M. Heuser − Status of the Silicon Tracking System

  48. Project plan, iMoU, Writeups, TDR • Request by the Technical Coordinator: • Comprehensive Sub-System Note during Q3 2010 • Design Review during Q1 2011 (CBM organized, external Reviewers) • TDR's in Q1 2012 • Project plan within Interim Memorandum of UnderstandingDRAFT – being updated • Participating Institutes • Work share during R&D phase, Construction phase less clear • Tasks, timelines and deliverables • not covered tasks + teams • Costs • STS construction + commissioning timeline: adapt to new FAIR schedule J.M. Heuser − Status of the Silicon Tracking System

  49. Test beam at GSI, 21-26 June 2010 preliminary – beam scheduling meeting on 19 April • cave C • beam line HTD • beam: Nitrogen • 0.8 GeV/u • on a target J.M. Heuser − Status of the Silicon Tracking System

More Related