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Published byReynard Dawson Modified over 8 years ago
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Status of the STAR tracking upgrade Gerrit van Nieuwenhuizen STAR Collaboration Meeting BNL, February 24, 2005
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Physics Probing gluon polarization Gluon contribution to the proton spin: Gluon contribution to the proton spin: Inclusive- and di-jet production Inclusive- and di-jet production Inclusive p i-zero production Inclusive p i-zero production Prompt photon production Prompt photon production Heavy-Flavor production Heavy-Flavor production Flavor decomposition of quark and anti-quark polarization in W production STAR pp/spin STAR Heavy-Ion Heavy-Flavor physics Spectra Spectra Elliptic flow Elliptic flow Heavy-Flavor energy loss Heavy-Flavor energy loss Vector mesons Vector mesons
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Tracker requirements W production Tracking in forward direction, 1<eta<2 Tracking in forward direction, 1<eta<2 e+/e- charge discrimination, sagitta ~2.5mm for Pt~30GeV/c e+/e- charge discrimination, sagitta ~2.5mm for Pt~30GeV/c Fast detector and readout Fast detector and readout Heavy Ion program (& pp Heavy-Flavor) High precision tracking High precision tracking DCA resolution of ~20um DCA resolution of ~20um Low mass Low mass Connect uvertex detector with TPC Connect uvertex detector with TPC Deal with overlapping events with high multiplicities Deal with overlapping events with high multiplicities
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Required layout 3 layer barrel & 4 forward disks of stereo angle silicon strip pairs 100% 3-hit efficiency for -5 < Zvertex < +5cm (for hermetic layers) 94% 3-hit efficiency for -10 < Zvertex < +10cm
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Technology choices Conservative Existing APV25-S1 readout chip (CMS) Single sided ac-coupled silicon strip sensors (contact with Hamamatsu established) (contact with Hamamatsu established) Triple foil GEM detectors
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Status of mechanical design Jim Kelsey (Bates) working on mechanical integration
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Layer 1 Layer 2 Inner Star/Silicon Tracker Layer 3 11/154 19/380 27/702 Ladders/Sensors Using 40x40 mm^2 single sided silicon strip sensors arranged in stereo pairs
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Forward Star/Silicon Tracker 4 disks 21 sectors per disk 4 sensors per sector (stereo, back-to-back (stereo, back-to-back
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Heavy-Flavor Tracker See Kai Schweda's talk
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Forward GEM Tracker Mechanical design by Jim Kelsey (Bates) See also Bernd Surrow's talk 180 identical(!) triple GEM chambers
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Status of simulation geometry HFT + IST fit inside the SSD But the mechanical integration will take quite a bit of work
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Status of simulation geometry SSD IST HFT FST FGT Original implementation by Maxim Potekhin
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Simulation geometry SSD Very complete implementation!
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Simulation geometry IST 3 layers at 70, 120 and 170mm 57 ladders 1236 silicon sensors thermal plates and substrates readout chips (approximated) cooling channels
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Simulation geometry HFT Very basic implementation Also the mechanical construction should be modeled
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Simulation geometry FST 4 disks at z = 280, 310, 340 and 370mm and 370mm 21 wedges per disk 336 silicon sensors thermal plates and substrates readout chips (approximated) cooling channels (approximated)
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Simulation geometry FGT Argon/Carbondioxide volumes with G10 and Kapton with G10 and Kapton
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Fast simulations Minimal preliminary geometry First step to look at e+ e- charge separation Still working on framework
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Full blown simulations Focus on occupancy for high luminosity Au+Au and charge separation for polarized p+p charge separation for polarized p+p
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Readout R&D APV25-S1 readout chip Single chip readout board GEM readout board with chip piggy-backs 20 boards ordered Same readout system for GFT, IST and FST! DAQ1000 compatible Profiting from TOF developments
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Readout R&D Readout system for GEM's well underway See talk by Miro Plesko
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Participating institutions, so far....
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Active human resources DAQ & chip readout Miro Plesko Miro Plesko Dave Underwood Dave Underwood Mechanical design Gerrit van Nieuwenhuizen Gerrit van Nieuwenhuizen Jim Kelsey Jim Kelsey Doug Hasel Doug Hasel Silicon procurement Gerrit van Nieuwenhuizen Gerrit van Nieuwenhuizen GEM R&D Doug Hasel, Bernd Surrow Doug Hasel, Bernd Surrow Dick Majka, Nicolai Smirnov Dick Majka, Nicolai Smirnov Hal Spinka, Dave Underwood Hal Spinka, Dave Underwood Kerry Kernie (Tech Etch) Kerry Kernie (Tech Etch) GEANT geometries Maxim Potekhin Maxim Potekhin Gerrit van Nieuwenhuizen Gerrit van Nieuwenhuizen Dave Underwood (TPC endcap) Dave Underwood (TPC endcap)Simulations Mike Miller Mike Miller Mirko Planinic Mirko Planinic Willie Leight Willie Leight System integration TBA TBACoordination Bernd Surrow Bernd Surrow
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Time lines Current scenario Stage 1: Active pixel HFT with a minimal IST Stage 1: Active pixel HFT with a minimal IST based on silicon strip technology based on silicon strip technology Proposal HFT in beginning of 2005 Proposal HFT in beginning of 2005 Proposal IST in summer 2005 Proposal IST in summer 2005 Installation in summer 2008 Installation in summer 2008 Stage 2: Upgrade forward tracking with IST Stage 2: Upgrade forward tracking with IST and FGT and FGT Proposal FST and FGT in summer 2006 Proposal FST and FGT in summer 2006 Installation in summer 2009 Installation in summer 2009
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