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Peter Križan, Ljubljana Peter Križan University of Ljubljana and J. Stefan Institute The HERA-B RICH counter.

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Presentation on theme: "Peter Križan, Ljubljana Peter Križan University of Ljubljana and J. Stefan Institute The HERA-B RICH counter."— Presentation transcript:

1 Peter Križan, Ljubljana Peter Križan University of Ljubljana and J. Stefan Institute The HERA-B RICH counter

2 Peter Križan, Ljubljana 920 GeV protons p + A  X @  s = 41.6 GeV The HERA-B Experiment

3 Peter Križan, Ljubljana The HERA-B Detector

4 Peter Križan, Ljubljana HERA-B RICH Requirements: High QE over ~3m 2 Rates ~1MHz per channel Long term stability NIM A516 (2004) 445

5 Peter Križan, Ljubljana HERA-B RICH: rates on the photon detector Few MHz per channel

6 Peter Križan, Ljubljana HERA-B RICH photon detector Cadidates – original: CsI based wire chamber with pads TMAE based wire chamber with ‘egg-crate’ structure Backup solution: Multianode PMTs Hamamatsu R5900 series

7 Peter Križan, Ljubljana CsI chamber A lot of very good results  NIM A300 (1991) 213; NIM A307 (1991) 145; NIM A364 (1995) 243 Beam test, accumulated rings  NIM A371 (1996) 151

8 Peter Križan, Ljubljana CsI chamber Show-stoppers for the use in HERA-B: High rate instabilities  NIM A371 (1996) 151 Ageing  NIM A387 (1997) 146

9 Peter Križan, Ljubljana TMAE chamber Photons enter the chamber from the left. Optical thickness: along the anode wires. Rather fast (<100ns) cc

10 Peter Križan, Ljubljana TMAE chamber Excellent performance: No feed-back photons Stable at high rates NIM A371 (1996) 289 Show-stopper for HERA-B: ageing NIM A414 (1998) 170 Possible remedy: heating in situ NIM A515 (2003) 302

11 Peter Križan, Ljubljana HERA-B RICH photon detector Status in 1996: TMAE and CsI have serious problems in long term operation at very high rates Hamamatsu just came out with the metail foil multianode PMTs of the R5900 series: first multianode PMTs with very little cross-talk Tested on the bench and in the beam: excellent performance  easy decision  NIM A394 (1997) 27

12 Peter Križan, Ljubljana Multianode PMTs Hamamatsu R5900-M16 (4x4 channels) R5900-M4 (2x2 channels) Key features: Single photon pulse height spectrum Low noise Low cross-talk

13 Peter Križan, Ljubljana Multianode PMTs Uniformity: Large variation (3-4x) in amplification – no problem in photon counting (in case of low noise) Good uniformity in QE x photo-electron collection efficiency QE x collect. eff.  NIM A478 (2002) 391

14 Peter Križan, Ljubljana HERA-B RICH tiling scheme Match the occupancy and resolution needs: Finer granularity in the central part Upper detector half: M16 PMTs M4 PMTs

15 Peter Križan, Ljubljana Multianode PMTs Large statistics (2300 pcs) QA tests  NIM A442 (2000) 316

16 Peter Križan, Ljubljana Multianode PMT read-out Front-end readout electronics: Based on ASD8 read-out chips ASD8 = 8 channel amplifier, shaper and discriminator: ● ENC ~ 900 + 70/pF ● shaping time ~ 10ns ● sensitivity ~ 2.5mV/fC ASD8 board: 16 channels (2 x ASD8 chips)  NIM A541 (2005) 610 Voltage divider: integrated in the PMT base board

17 Peter Križan, Ljubljana Light collection system Light collection system (imaging!) to: -Adapt the pad size -Eliminate dead areas

18 Peter Križan, Ljubljana Light collection system Light collection system features: -Only slightly aspheric -Easy to fabricate plastic lenses -Mold production, cheap -Integrated into the support structure T   of the lens system, QE   of PMT 

19 Peter Križan, Ljubljana Mechanics inside outside

20 Peter Križan, Ljubljana Photon detector: Upper half

21 Peter Križan, Ljubljana Photon detector form Minimize the error due to spherical aberration. Specific: Mirror tilted by 9 0. The optimal surface could be approximated by a deformed cyllinder, by about 20cm from the naive focal surface at R/2, and slightly tilted.  NIM A433 (1996) 124

22 Peter Križan, Ljubljana Mirrors Spherical mirrors: R=11.5m, hexagons of 7mm Pyrex glass, coated with 200nm Al and 30 nm of MgF 2 Planar mirrors: rectangles of float glass

23 Peter Križan, Ljubljana Mirrors Each segment: computer controlled motors for alignment

24 Peter Križan, Ljubljana Mirrors - alignment Initial alignment: with teodolite inside the vessel Final alignment: using data Use rings with photons from different mirror segments for relative alignment  NIM A433 (1999) 408

25 Peter Križan, Ljubljana HERA-B RICH performace Little noise, very clear rings with ~30k read- out channels

26 Peter Križan, Ljubljana Performance Typical event... Background mainly from other tracks  adapt the extented maximum likelihood analysis with expectation-maximisation algorithm  NIM A433 (1999) 279

27 Peter Križan, Ljubljana Performance Figure of merit: N 0 =42/cm (=expected) Number of photons for =1 particles: 33 Single photon resolution:    0.8 mrad for finer granularity region (R5900-M16 tubes)   .0 mrad for coarser granularity region (R5900-M4 tubes) Well separated particle bands

28 Peter Križan, Ljubljana Performace It actually works very well!  NIM A516 (2004) 445 Idenfication of pions: pion efficiency, p, K fake probability Idenfication of kaons: K efficiency, pion fake probability Idenfication of protons: p efficiency, K fake probability

29 Peter Križan, Ljubljana Summary R5900 MA PMTs have proven to be an extremly reliable and easy to use detector for Cherenkov photons. Several new methods were developed for the design of the detector surface, analysis of data and alignment of the optical system. The HERA-B RICH counter showed an excellent performance in very adverse conditions.

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