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V. Korbel, DESY1 Progress Report on the TESLA Tile HCAL Option To be filled soon
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V. Korbel, DESY2 The HCAL Calorimeter for the TESLA Detector at DESY A Tool for Energy Flow Measurement: The calorimeter is used: to separate clusters from charged and neutral particles to measure energy and position (> angle) of neutrals to track minimum ionising particles This requires: rather good energy resolution, very fine granularity of cells compared to existing hadronic calorimeters. At TESLA 2 HCAL options under study: sandwich scintillator/absorber calorimeter with tile structure digital sandwich calorimeter with very fine granularity.
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V. Korbel, DESY3 TESLA Detector, cross section Energy Flow Measurement: additional information from: vertex detector intermediate trackers TPC >> vertex of event momentum of charged tracks particle identification particle impact point at ECAL
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V. Korbel, DESY4 TESLA Detector, cross section, more details Barrel HCAL Endcap HCAL Endcap Yoke HCAL Small angle calorimeters Full hermeticity down to < xx mrad
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V. Korbel, DESY5 Cut across the barrel calorimeter 16 tapered modules 8 x symmetry Sandwich layers, 38 (53) max: 5 mm scintillator 1.5 mm gap for fibre RO, reflector foil 20mm Fe absorber 1 s/w layer =1.15 X 0, 0.12
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V. Korbel, DESY6 The layer structure of the HCAL Sandwich layers; 38 in barrel,45 in end caps with scintillator tiles: sizes: ~5x5......~16x16 cm 2 ~ 800 000 tiles Cells: cells are non projective 9 (10) cell layers in barrel (end cap), grouped from 3,3,3,4,4,4,5,5,7 (3,3,3,4,4,4,5,5,7,7) s/w layers cell volumes: (0.22 ) 2 x0.36 (0.71 ) 2 x0.84 (1.6 R Moliere ) 2 x 3.5 X 0...(5 R Moliere ) 2 x 8 X 0 ~160 000 cells Optimal HCAL granularity for E-Flow reconstruction of jet energies, ~angles and jet-jet masses.
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V. Korbel, DESY7 The calorimeter modules: 10 cell layers additional front side ring surrounding end cap ECAL One of 32 Barrel HCAL modules Some free space left 1 quadrant assembled to wheel End cap HCAL 9 cell layers
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V. Korbel, DESY8 The complete calorimeter Containment: barrel: 1.1+4.5 =5.6 endcaps 1.1+5.2+5.6 =11.9 Beam hole is closed by the mask calorimeter (Lumi-measurement) tungsten (electromagnetic shield) graphite (neutron shield)
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V. Korbel, DESY9 original fibre RO concept as described in the TESLA-TDR. Original concept of tile plate read out 1. layer Problematic are the small scintillator tile sizes (~ 5x5 cm 2 ) to be read out Study other possibilities
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V. Korbel, DESY10 R&D studies on the tile-WLS fibre system Green WLS fibre: attenuation length Scintillator light yield Tile uniformity Reflector foil: mirror or diffraction, light yield Reflector foil: LY uniformity WLS fibre: bending in small radius WLS fibre: ageing, rad. hardness WLS fibre: fibre end polishing and mirroring Tile-WLS system: coupling, light yield, uniformity >>>> 5x5 cm 2, than: 7x7......16x16cm 2 tiles Tile-WLS system: coupling, light yield, uniformity >>>> 5x5 cm 2, than: 7x7......16x16cm 2 tiles Scintillator : ~6600 m 2, costs! R&D Y-11, Kuraray BC-91, Bicron BC-408, BC-416, SC-306, Protvino Tyvek, 3M Super-reflector Al-vapour, various reflector paintings,polished optimally
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V. Korbel, DESY11 Details of TFS optimisation studies Centre/straight fibreDiagonal/bent fibre Double looped fibre No stress on fibre, L= cm fibre refl. =tile reflector more stress on fibre, L= cm fibre refl. =tile reflector most stress on fibre, probably ageing L= cm fibre refl.inside tile > special reflective coating needed WLS-clear fibre connection easy to implement here clear RO fibre to couple: max. attenuation length
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V. Korbel, DESY12 R&D studies Yield of channel in recalibration >> design of detector construction features some R&D results the minical the HCAL prototype performance, preliminary
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V. Korbel, DESY13 WLS fibre end polishing Enlarged view, 20 m Polished with 3 m and 0.3 m sand-micro-polishing paper
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V. Korbel, DESY14 Yield of different TF configurations: Some results:
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V. Korbel, DESY15 Light yield and uniformity for tiles 4.0 – 5.55.0 – 6.54.0 – 6.0Uniformity (%) 15 x 15 10 x 10 5 x 5Tile (cm 2 ) 16 +- 2.815 +- 1.416 +- 1.7LY / photo e - (nA) 2.5 +- 0.24 +- 0.26.5+-0.4Photo e - 11.5 +- 0.32.4 +- 0.4Relative LY 39 +- 660 +- 4105 +- 6LY (nA) 15 x 1510 x 10 5 x 5Tile a x a (cm 2 ) improve LY for large tiles with WLS loops signal of large cells will be increased by more sampling layers actual established LY is ~20 pe/cell/MIP uniformity is ok, needs confirmation by simulation studies. light yield uniformity
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V. Korbel, DESY16 Achievements of the TFS studies: 1. Scintillator: Bicron BC-408, Russian scint. SC301, 65% yield 2. 3M Super-reflector 3. Kuraray Y-11 4. Open WLS-end only polished (~0.3 m) 4. WLS-fibres glued to tile 5. Diagonal bent fibre insertion 6. Light yield adjustment with reflector dimmer strip ( +/- 4-5%) More: --ageing studies --uniformity trimming
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V. Korbel, DESY17 Assembled from up to 27 scintillator layers: 165 tiles of: 5x5 cm 2 >> 45 cells 10x10 cm 2 >> 8 cells 20x20 cm 2 >> 2 cells read out by WLS fibres (without clear RO fibres) to photodetectors --3x16 MA-PM’s,(H8711), --1x32 APD array,(H-s8550) --Si-PM’s. Tile and sandwich structure Track cambers? A pre-prototype : the „minical“-array For cosmics and e-beam tests Cell structure
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V. Korbel, DESY18 The need of a HCAL prototype Study with pions, electrons and muons: ---stand alone runs: cluster development and separation angular resolution longitudinal and lateral containment threshold stability and cross-talk software compensation calibration with muons stability of LED monitoring noise contribution energy resolution measure the constant term ---together with an ECAL prototype: Energy Flow properties, Electron-Pion separation ---compare with digital HCAL version (same HCAL iron stack structure) To tune the simulation programs and optimise the reconstruction !
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V. Korbel, DESY19 HCAL prototype Required volume ~ 1 m3 ~ 800-1200 calorimeter cells Fe-structure is same for analogue and digital HCAL 10 GeV pions 100 GeV pions 100 cm Leakage detector needed!
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V. Korbel, DESY20 Best coupling shape for WLS fibres? Loops ph.e./tile ph./cell 1 7.7 184 2 10.5 256 3 10.0 240 unbent fibres: along edge, no groove: 7.0 168 along groove in centre 7.7 184 diagonal fibre, groove: 10.5 256 diagonal, minimal bend: 11.0 264 Other criteria to use unbent fibres: easy to insert, less risk of damage no bending stress, > less ageing
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V. Korbel, DESY21 The HCAL Calorimeter for the TESLA Detector at DESY A Tool for Energy flow measurement: The calorimeter is used: to separate clusters from charged and neutral particles to measure energy and position (>angle) of neutrals to track minimum ionising particles This requires rather good energy resolution, very fine granularity of cells compared to existing HCALs. At TESLA 2 HCAL options under study: sandwich scintillator/absorber calorimeter with tile structure digital sandwich calorimeter with very fine granularity.
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V. Korbel, DESY22 Summary List of talks: How to continue:
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V. Korbel, DESY23 Last transparency List of talks: How to continue:
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