V.Dzhordzhadze1 Nosecone Calorimeter Simulation Vasily Dzhordzhadze University of Tennessee Muon Physics and Forward Upgrades Workshop Santa Fe, June 22,

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Presentation transcript:

V.Dzhordzhadze1 Nosecone Calorimeter Simulation Vasily Dzhordzhadze University of Tennessee Muon Physics and Forward Upgrades Workshop Santa Fe, June 22, 2004

V.Dzhordzhadze2 Forward calorimeter for PHENIX upgrade Geometry and composition Simulation of performance Resolutions Event display Summary Outline

V.Dzhordzhadze3 PISA View of PHENIX

V.Dzhordzhadze4 Nosecone HCAL J/  Width Signal  x 0 GeV/c 2 events Cu 19 cm No 155+/ / W 9 cm No 163+/ / W 7 cm No 155+/ / W 9 cm Yes 175+/ / W 7 cm Yes 162+/ / J/  ->    - Yield and Resolutions

V.Dzhordzhadze5 Details of the Geometry

V.Dzhordzhadze6 Tungsten 2.5 mm or 16.6 mm Ka 0.2 mm G mm Si 0.3 mm Air 1.2 mm 4-40 cm 4-50 cm Materials used in NCC

V.Dzhordzhadze7 front view side view 40 cm 20 cm  /  0 identifier EM hadronic Incoming electron (10GeV)  First 8.0cm: 16 layers of Tungsten (2.5 mm), Si(0.3 mm), G10(0.8 mm), Kapton (0.2 mm) and Air(1.2 mm). –After first 6 layers there is a 0.5mm thick double layer of Si,G10,Kapton,Air (this is the  /  0 identifier).  Second half has a 6 layers with same sequence of materials, only thickness of Tungsten 16.6 mm. 10 GeV electron

V.Dzhordzhadze8 Internal structure (not in scale). Tungsten plates 2.5 mm Spacers glued to W 2.5 mm How to build this calorimeter ….. Constrains: -Structure in place prior to SVT installation; -Easy access for repairs/replacements; -Minimal power consumption – no forced cooling; -Compact signal processing plant – no competition for the real estate on magnet pole;

V.Dzhordzhadze9 Section 1, 2 and 3 : Pad size 15 x 15 mm +/-36 cm 2304x16= /-48 cm 4096x6=24576 Total number of channels  /   identifier 60mm/32 1 strip =1.875 mm 384x2=768 Number of channels

V.Dzhordzhadze10 Energy Reconstruction E =  1 E 1 +  2 E 2 +  3 E 3  = (     E  – E ) 2 d  /d  1 = 0 d  /d  2 = 0 d  /d  3 = 0 System of Linear equations  1 = 66.97,  2 = 84.29,  3 =

V.Dzhordzhadze11 Resolution for 10 GeV electron

V.Dzhordzhadze12 Resolution for 1,5,10,40 GeV electron

V.Dzhordzhadze13 Energy Resolution E 1/2  MeV

V.Dzhordzhadze14 Energy Resolution  MeV E 1/2

V.Dzhordzhadze15 Shower profiles for 10 GeV electron X Z

V.Dzhordzhadze16 J/  e + e - in NCC

V.Dzhordzhadze17 Coordinate resolution for J/  e + e  m

V.Dzhordzhadze18 J/  e + e - mass spectrum  MeV

V.Dzhordzhadze19 40 GeV electron display

V.Dzhordzhadze20 40 GeV pion display

V.Dzhordzhadze21 Geant3 based NCC simulation code was developed NCC resolution ~ (20-23)%/E 1/2 obtained Written a simple cluster searching and reconstruction code, allowing energy reconstruction in NCC Coordinate resolution of the  detector < 1 mm J/  -> ee decay and reconstruction by the NCC was performed. 72% of events were reconstructed:  = 462 MeV Code will be included in PISA Summary

V.Dzhordzhadze22 J/  ->    - Mass spectrum