B W Kennedy, CCLRC Rutherford Appleton Laboratory VPTs for the CMS experiment B W Kennedy CCLRC Rutherford Appleton Laboratory St Petersburg, 26 April.

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Presentation transcript:

B W Kennedy, CCLRC Rutherford Appleton Laboratory VPTs for the CMS experiment B W Kennedy CCLRC Rutherford Appleton Laboratory St Petersburg, 26 April 2005

B W Kennedy, CCLRC Rutherford Appleton Laboratory Outline of talk 1.Description of CMS Electromagnetic Calorimeter 2.Experimental conditions and challenges 3.Selection of Vacuum PhotoTriodes (VPTs) 4.Experience with VPTs from RIE 5.Conclusion

B W Kennedy, CCLRC Rutherford Appleton Laboratory The CMS Electromagnetic calorimeter PbWO 4 crystals ~61000 in barrel ~15000 in endcaps Pointing geometry Length: 6m Radius: 1.75m Depth: X 0 Target energy resolution: <1% at E = 100 GeV Endcap detail (“supercrystals”)

B W Kennedy, CCLRC Rutherford Appleton Laboratory Details of the SuperCrystal Basic unit –Supercrystal 5  5 array of crystals Carbon-fibre alveolar PbWO 4 crystals Radiation hard X 0 = 8.9 mm Fast scintillation 90% light in 100ns Mechanically fragile Low light yield ~50  /MeV

B W Kennedy, CCLRC Rutherford Appleton Laboratory Challenges for ECAL photodetector High radiation environment Dose is strong function of angle to proton beams Barrel: Up to 4 kGy in 10 years of LHC running Endcap: kGy in 10 years Fast response required Interval between LHC beam crossings is only 25ns Low light yield from PbWO 4 Approximately 50 photons/MeV  need device with gain CMS choices Barrel – Avalanche PhotoDiodes Endcap – Vacuum PhotoTriodes (VPTs)

B W Kennedy, CCLRC Rutherford Appleton Laboratory Structure of Vacuum PhotoTriode Single-stage photomultiplier Gain ~ 10 Light 0V 1000V 800V Photocathode Grid anode Dynode

B W Kennedy, CCLRC Rutherford Appleton Laboratory Specification for CMS VPTs Radiation tolerance Less than 10% loss in output after 20 kGy Quantum efficiency p p  15% for light of wavelength 420nm Gain g at zero magnetic field g  7 Magnetic field response Loss in yield at 4T < 15% with respect to 0T Stable (  10%) at angles up to 26 ° to magnetic field

B W Kennedy, CCLRC Rutherford Appleton Laboratory Selection of VPTs Prototypes supplied by several manufacturers Electron Tubes Hamamatsu Meltz Photonis Research Institute Electron Testing and evaluation up to 1999 Most manufacturers were able to meet specifications Tendering for contract in 1999 Successful tender from RIE to supply VPTs

B W Kennedy, CCLRC Rutherford Appleton Laboratory Typical response of prototype VPTs VPT response vs angle in 1.8T magnetic field VPT response vs field at 15 ° Variation of gain with applied voltage

B W Kennedy, CCLRC Rutherford Appleton Laboratory Radiation tolerance of faceplate glass  dose varies strongly with angle. All VPT faceplate glass tested to 20 kGy at Brunel University. Glass batch accepted if <10% transmission loss (convoluted over PbWO 4 spectrum) after 20kGy.

B W Kennedy, CCLRC Rutherford Appleton Laboratory Delivery of VPTs

B W Kennedy, CCLRC Rutherford Appleton Laboratory VPT testing procedure Two UK testing facilities Up to 1.8T at RAL All VPTs, variable angle 4T system at Brunel University Sample testing (10%), fixed angle

B W Kennedy, CCLRC Rutherford Appleton Laboratory Measurements on VPTs Response measured at RAL in 1.8T magnetic field. Consistent VPT response from batch to batch. Correlation between 0T measurements at RIE and 1.8T measurements at RAL

B W Kennedy, CCLRC Rutherford Appleton Laboratory 4T to 0T relative response Measured at Brunel University. VPT at 15 ° to magnetic field.

B W Kennedy, CCLRC Rutherford Appleton Laboratory Resolution of problems Regular meetings between RIE and CMS groups at CERN, RAL, RIE. Some problems inevitable in long production run. Most significant – discharges seen in small fraction VPTs. Exchange of information between CMS groups and RIE, and careful investigation by RIE experts  improvement in manufacturing procedure to reduce number of VPTs with discharges. VPT 790 Initial spike Example of discharge in VPT response Fraction of VPTs showing discharge Change to procedure

B W Kennedy, CCLRC Rutherford Appleton Laboratory Conclusions VPTs supplied by RIE meet needs of the CMS experiment. Delivery of VPTs is on schedule. Regular and open meetings between CMS and RIE enable problems to be solved. We look forward to the successful conclusion of the contract in February 2006.