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Premium member Presentation Transcript The CMS Electromagnetic Calorimeter: The CMS Electromagnetic Calorimeter Roger Rusack The University of Minnesota On behalf of the CMS ECAL collaboration Detector Overview: Detector Overview MUON BARREL CALORIMETERS ECAL Scintillating PbWO4 crystals Cathode Strip Chambers ( ) CSC Resistive Plate Chambers ( ) RPC Drift Tube Chambers ( ) DT Resistive Plate Chambers ( ) RPC IRON YOKE TRACKER MUON ENDCAPS HCAL Plastic scintillator/brass sandwich Goals: Goals High Resolution calorimetry: Stochastic term 2.7%, Constant term 0.5%, Noise term 150 – 220 MeV. Large volume: 75,848 crystals covering |h| < 2.6. 90.8 tons of crystals or 10.9 m3. Operated inside a 4T magnetic field. In a radiation environment with an integrated dose of: 1013 neutrons/cm2 and 1 kGy at h = 0 to 2×1014 neutrons/cm2 and 50 kGy for h = 2.6. 40 MHz bunch crossing rate.Lead Tungstate Crystals: Lead Tungstate Crystals Operate at 18o C – Temp dependence = -2.2%/OC. Radiation length – 0.83 cm Molière radius – 2.2 cm. Fast light output – 80% in 25 nsec. Relative Light Yield – 1.3% NaI No long-lived radiation damage. But short-lived metastable color centers created by radiation – careful monitoring Transmission Emission 350 nmConstruction Overview: Construction Overview 10 crystals Submodule Module Barrel 61,200 PbWO4 crystals Readout with 122,400 APD’s Endcap 14684 crystals readout with VPT’s. Preshower: Preshower Two-layer silicon preshower detector placed in front of the endcap calorimeters 2 Xo absorber 1 Xo absorber 2mm silicon strips to separate g’s from po’s and for vertex identification. Crystals and crystal production.: Crystals and crystal production. Transmission at 420nm Light Yield All crystals are tested for: Radiation Hardness, Light Yield, Physical Dimensions. Light yield uniformity. Projection is 3o off interaction point - 34 different crystal types. Barrel Crystals are tapered – variation of reponse with origin of the shower. Correct by roughening one surface of the crystal.Photodetection: Photodetection 4T B-field precludes use of PMT’s.. Avalanche photodiodes in barrel. Vacuum Phototriodes in Endcap Two 5× 5 mm2 APD’s/crystal. Gain – 50. QE – 80% @ 420 nm. Temp sensitivity – -2.4%/ OC. Gain – 10. QE – 15% @ 420 nm. Rad tolerance - <10% at 20 kGy. Operates in high B – field. Readout Overview: Readout Overview Each crystal has a low-noise, large dynamic range pre-amplifier with three gain outputs each coupled to a separate 40 MHz ADC, to cover the full 50 MeV to 1 TeV range. Level 1 trigger sums are sent every bunch crossing. Data from each crossing is stored until level 1 trigger accept. All data are sent on fiber optic links. Supercrystal Front-end board Data Trigger sums Very Front End board GOH APD MGPA 3 ADC’sFront-End Electronics: Front-End Electronics Barrel – Grouped into a 5 × 5 crystal array. Endcap – Grouped to match h - f Crystal APD Amplifier *1 Amplifier *6 Amplifier *12 ADC Channel 2 (12bit) ADC Channel 1 (12 bit) ADC Channel 0 (12 bit) 14 bit Channel Data Single channel architecture FE Board 25 Trigger Link Data Link Creation of trigger primitives. Storage of data to level 1 accept. Signal from APD’s ~100 W per trigger tower. Total power on detector ~ 50kA, 300 kW. All front-end electronics in 0.25m process. Optical Data Links: Optical Data Links All data is sent off detector electronics via 1 GHz Optical links. 10,500 links for whole calorimeter – Data flow: 10 Tb/sec. Radiation hard Off detectorCooling: Cooling All 0.25 m electronics runs at 2.5V. 0.45 A/channel 1 A/board Radiation hard regulator has a drop out voltage of 1.5V Total power in whole calorimeter ~300 kW Crystal light yield decreases by 2.2%/oC & APD gain decreases by 2.3%/OC. Removing all excess heat is critical for the stable operation of the detector. Cooling: Cooling Trigger tower on the cooling bars 0.04°C 2 months Approach: isolate crystals and APD’s from electronics. Remove heat from electronics by close coupling with water cooled bars. Crystals and APD’s dT kept to 0.05oC & uniform to 0.2oC. Temperature stability with a 100-channel system last year.Test beam : precalibration: Test beam : precalibration We cannot test calibrate every crystal with an electron beam. Obtain a first calibration point from component data: crystal light yield, APD & pre-amplifer gain. In situ: Fast intercalibration based on f symmetry in minimum bias events 2% in few hours Energy/momentum of isolated electron from W→ en 0.5% in 2 months Absolute energy scale from Z → e+e- Test Beam LY Labo LY corr s = 4.05% Test Beam LY – Labo LY corr Relative channel calibration can be obtained from lab with a precision of 4 % Monitor Laser System: Monitor Laser System Three laser system. ND:YLF laser that pumps a Q-switched Ti-Saphire laser to monitor short term variations in the crystal transmission. Pulse with same time structure as the scintillator at a frequency of 440 nm. APD F1 F2 PIN FE Laser S PWO 440 nm 796 nm Laser light injected at the front side of the crystals.Monitoring: Monitoring Resolution before and after an induced large change in light output.Results from Test beam with final electronics.: Results from Test beam with final electronics. Resolution(mm) Energy (GeV) 1 mm Energy (GeV) Energy Position 0.6% at 50 GeV. 0.85 mm at 50 GeV. Resolution(%) You do not have the permission to view this presentation. In order to view it, please contact the author of the presentation.
9 0568 rusack r Mahugani Download Post to : URL : Related Presentations : Share Add to Flag Embed Email Send to Blogs and Networks Add to Channel Uploaded from authorPOINTLite Insert YouTube videos in PowerPont slides with aS Desktop Copy embed code: (To copy code, click on the text box) Embed: URL: Thumbnail: WordPress Embed Customize Embed The presentation is successfully added In Your Favorites. Views: 46 Category: Entertainment License: All Rights Reserved Like it (0) Dislike it (0) Added: November 20, 2007 This Presentation is Public Favorites: 0 Presentation Description No description available. Comments Posting comment... Premium member Presentation Transcript The CMS Electromagnetic Calorimeter: The CMS Electromagnetic Calorimeter Roger Rusack The University of Minnesota On behalf of the CMS ECAL collaboration Detector Overview: Detector Overview MUON BARREL CALORIMETERS ECAL Scintillating PbWO4 crystals Cathode Strip Chambers ( ) CSC Resistive Plate Chambers ( ) RPC Drift Tube Chambers ( ) DT Resistive Plate Chambers ( ) RPC IRON YOKE TRACKER MUON ENDCAPS HCAL Plastic scintillator/brass sandwich Goals: Goals High Resolution calorimetry: Stochastic term 2.7%, Constant term 0.5%, Noise term 150 – 220 MeV. Large volume: 75,848 crystals covering |h| < 2.6. 90.8 tons of crystals or 10.9 m3. Operated inside a 4T magnetic field. In a radiation environment with an integrated dose of: 1013 neutrons/cm2 and 1 kGy at h = 0 to 2×1014 neutrons/cm2 and 50 kGy for h = 2.6. 40 MHz bunch crossing rate.Lead Tungstate Crystals: Lead Tungstate Crystals Operate at 18o C – Temp dependence = -2.2%/OC. Radiation length – 0.83 cm Molière radius – 2.2 cm. Fast light output – 80% in 25 nsec. Relative Light Yield – 1.3% NaI No long-lived radiation damage. But short-lived metastable color centers created by radiation – careful monitoring Transmission Emission 350 nmConstruction Overview: Construction Overview 10 crystals Submodule Module Barrel 61,200 PbWO4 crystals Readout with 122,400 APD’s Endcap 14684 crystals readout with VPT’s. Preshower: Preshower Two-layer silicon preshower detector placed in front of the endcap calorimeters 2 Xo absorber 1 Xo absorber 2mm silicon strips to separate g’s from po’s and for vertex identification. Crystals and crystal production.: Crystals and crystal production. Transmission at 420nm Light Yield All crystals are tested for: Radiation Hardness, Light Yield, Physical Dimensions. Light yield uniformity. Projection is 3o off interaction point - 34 different crystal types. Barrel Crystals are tapered – variation of reponse with origin of the shower. Correct by roughening one surface of the crystal.Photodetection: Photodetection 4T B-field precludes use of PMT’s.. Avalanche photodiodes in barrel. Vacuum Phototriodes in Endcap Two 5× 5 mm2 APD’s/crystal. Gain – 50. QE – 80% @ 420 nm. Temp sensitivity – -2.4%/ OC. Gain – 10. QE – 15% @ 420 nm. Rad tolerance - <10% at 20 kGy. Operates in high B – field. Readout Overview: Readout Overview Each crystal has a low-noise, large dynamic range pre-amplifier with three gain outputs each coupled to a separate 40 MHz ADC, to cover the full 50 MeV to 1 TeV range. Level 1 trigger sums are sent every bunch crossing. Data from each crossing is stored until level 1 trigger accept. All data are sent on fiber optic links. Supercrystal Front-end board Data Trigger sums Very Front End board GOH APD MGPA 3 ADC’sFront-End Electronics: Front-End Electronics Barrel – Grouped into a 5 × 5 crystal array. Endcap – Grouped to match h - f Crystal APD Amplifier *1 Amplifier *6 Amplifier *12 ADC Channel 2 (12bit) ADC Channel 1 (12 bit) ADC Channel 0 (12 bit) 14 bit Channel Data Single channel architecture FE Board 25 Trigger Link Data Link Creation of trigger primitives. Storage of data to level 1 accept. Signal from APD’s ~100 W per trigger tower. Total power on detector ~ 50kA, 300 kW. All front-end electronics in 0.25m process. Optical Data Links: Optical Data Links All data is sent off detector electronics via 1 GHz Optical links. 10,500 links for whole calorimeter – Data flow: 10 Tb/sec. Radiation hard Off detectorCooling: Cooling All 0.25 m electronics runs at 2.5V. 0.45 A/channel 1 A/board Radiation hard regulator has a drop out voltage of 1.5V Total power in whole calorimeter ~300 kW Crystal light yield decreases by 2.2%/oC & APD gain decreases by 2.3%/OC. Removing all excess heat is critical for the stable operation of the detector. Cooling: Cooling Trigger tower on the cooling bars 0.04°C 2 months Approach: isolate crystals and APD’s from electronics. Remove heat from electronics by close coupling with water cooled bars. Crystals and APD’s dT kept to 0.05oC & uniform to 0.2oC. Temperature stability with a 100-channel system last year.Test beam : precalibration: Test beam : precalibration We cannot test calibrate every crystal with an electron beam. Obtain a first calibration point from component data: crystal light yield, APD & pre-amplifer gain. In situ: Fast intercalibration based on f symmetry in minimum bias events 2% in few hours Energy/momentum of isolated electron from W→ en 0.5% in 2 months Absolute energy scale from Z → e+e- Test Beam LY Labo LY corr s = 4.05% Test Beam LY – Labo LY corr Relative channel calibration can be obtained from lab with a precision of 4 % Monitor Laser System: Monitor Laser System Three laser system. ND:YLF laser that pumps a Q-switched Ti-Saphire laser to monitor short term variations in the crystal transmission. Pulse with same time structure as the scintillator at a frequency of 440 nm. APD F1 F2 PIN FE Laser S PWO 440 nm 796 nm Laser light injected at the front side of the crystals.Monitoring: Monitoring Resolution before and after an induced large change in light output.Results from Test beam with final electronics.: Results from Test beam with final electronics. Resolution(mm) Energy (GeV) 1 mm Energy (GeV) Energy Position 0.6% at 50 GeV. 0.85 mm at 50 GeV. Resolution(%)