H.-G. Moser, Max-P lanck-Institut für Physik, Munich 1 Beauty03, October 2003 The Status of the ATLAS Inner Detector Hans-Günther Moser for the ATLAS Collaboration Outline • Introduction •Tracking in ATLAS • ATLAS ID •Pixel detector • Silicon Tracker • Transition Radiation Tracker • System Aspects • Schedule • Conclusions
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The Status of the ATLAS Inner Detector Hans-Günther Moser for the ATLAS Collaboration
The Status of the ATLAS Inner Detector Hans-Günther Moser for the ATLAS Collaboration. Outline Introduction Tracking in ATLAS ATLAS ID Pixel detector Silicon Tracker Transition Radiation Tracker System Aspects Schedule Conclusions. Requirements for Tracking in ATLAS. - PowerPoint PPT Presentation
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H.-G. Moser, Max-Planck-Institut für Physik, Munich
1Beauty03, October 2003
The Status of the ATLAS Inner Detector
Hans-Günther Moserfor the ATLAS Collaboration
Outline
• Introduction
•Tracking in ATLAS
• ATLAS ID
•Pixel detector
• Silicon Tracker
• Transition Radiation Tracker
• System Aspects
• Schedule
• Conclusions
H.-G. Moser, Max-Planck-Institut für Physik, Munich
2Beauty03, October 2003
Requirements for Tracking in ATLAS• Rapidity coverage: || < 2.5
• Occupancy: 700 tracks per high luminosity event inside acceptance
• Short bunch crossing time (25 ns)
• High radiation: up to 1014 neutrons/cm2/year (1 MeV equivalent)
H.-G. Moser, Max-Planck-Institut für Physik, Munich
3Beauty03, October 2003
ATLAS and ATLAS Inner Detector
ID length: 7 mID diameter: 2m
H.-G. Moser, Max-Planck-Institut für Physik, Munich
4Beauty03, October 2003
The ATLAS Inner Detector
Sub-Detector r(cm) element size resolution hits/track channels
Pixel 5-12.5 50m x400m 12m x 60m 3 93x106
(Silicon) (3D)
SCT 30-52 80m x 12cm 16m x 580m 4 6x106
(Silicon Strip) (stereo)
TRT 56-107 4 mm x 74cm 170m 36 0.4x106
(Straw Tubes) (projective)
Three subdetectors using different technologies to match the requirements of granularity and radiation tolerance
H.-G. Moser, Max-Planck-Institut für Physik, Munich
5Beauty03, October 2003
Pixel Detector LayoutPixel Detector Layout
3 barrel cylinders2 x 3 endcap disks
Insertable layout-> can be inserted after installation of SCT/TRD-> ‚easy‘ upgrade
Only the support tube needs to be installed beforehand
Decouples SCT/TRT and Pixel schedule
Last subdetector to be installed!
H.-G. Moser, Max-Planck-Institut für Physik, Munich
6Beauty03, October 2003
Pixel ModulesPixel ModulesEach Module (16.4 x 60.8 mm2) has one sensor with 46080 pixels16 frontend chips are bump-bonded on the sensor for readout
3 barrel layers need 1744 modules2x3 endcaps 288 modules
Sensors are in production: CiS (Germany): 600 produced, 400 in productionTesla (Czech Republic): 50 produced, full series to start
H.-G. Moser, Max-Planck-Institut für Physik, Munich
7Beauty03, October 2003
Pixel ElectronicsPixel Electronics
FE readout chip in Deep Submicron (DSM) technology(DMILL failed)First prototype batches basically working, however, some fixes necessaryProduction yield >90% !
MCCI2 (module control)New version with triple logic for SEU (single event upset) toleranceFinal production expected to be ready by now
H.-G. Moser, Max-Planck-Institut für Physik, Munich
8Beauty03, October 2003
Pixel SupportPixel Support
Support tube in production(needs to be ready first!)
Global support readyLocal supports (staves and sectors) in productionA bit late, but not critical
High precision/low mass objects
H.-G. Moser, Max-Planck-Institut für Physik, Munich
9Beauty03, October 2003
Test Beam ResultsTest Beam Results
before after
Efficiency:99.3% before irrad. 97.7% (60 Mrad)
Resolution:13.2 m after irradiation
Operation of 6 modules in parallel with one power supply/cable:No change of performance
H.-G. Moser, Max-Planck-Institut für Physik, Munich
10Beauty03, October 2003
SCT Layout
Four barrel layers-barrel radii: 300, 371, 443 and 514 mm; -length 1600 mm-in total 2112 modules
Forward Modules on 2x9 disks-disk distance from z = 0: 835 - 2788 mm, -radii: 259-560 mm -total of 1976 modules (3 rings: 40,40, 52 modules each)
H.-G. Moser, Max-Planck-Institut für Physik, Munich
11Beauty03, October 2003
SCT ModulesSCT Modules
strip direction
strip direction
Basic Concept (Endcap)
-4 Si-strip detectors in 2 planes (40 mrad stereo)
-Mechanical carrier made from Thermal Pyrolytic Graphite (Ck>1700 W/m/°K) and AlN
-Flex Hybrid (Kapton) on carbon substrate with ASIC readout electronics
-Glas pitch adaptors for mechanical/electrical connection detector-electronics (heat barrier)
H.-G. Moser, Max-Planck-Institut für Physik, Munich
12Beauty03, October 2003
SCT Silicon DetectorsSCT Silicon Detectors Radiation tolerant up to 3x10Radiation tolerant up to 3x101414 p/cm p/cm22
Forward: wedge shaped (5 shapesForward: wedge shaped (5 shapes)) 768 readout strips with ca 80 768 readout strips with ca 80 m pitchm pitch No intermediate stripsNo intermediate strips AC coupled stripsAC coupled strips Polysilicon or implanted bias resistorsPolysilicon or implanted bias resistors Multiguardring structure to ensure Multiguardring structure to ensure
stability up to 500 Vstability up to 500 V Ca. 20000 neededCa. 20000 needed Produced by HamaProduced by Hamamamatsu and CIStsu and CIS
After irradiation: high depletion voltageShort period (10 days): annealing reduces Vdep
Afterwards Vdep rises steadily with time (at high temperatures): Reverse annealing -> keep Si cool (-10 C)
Problems in very exposed regions close to the beam or high Reduced thickness: 285 -> 260 m ca. 50VOxigenated detectors: less damage and slower reverse annealing
H.-G. Moser, Max-Planck-Institut für Physik, Munich
14Beauty03, October 2003
SCT ElectronicsSCT Electronics
ABCD 128 channelsbipolar frontendDMILL rad hard processShaping time: 20nsBinary Readout (single threshold)132 cell pipeline
Production finishedLow yield, need to use chips with one dead channel to complete detector (ca. 15%)
H.-G. Moser, Max-Planck-Institut für Physik, Munich
15Beauty03, October 2003
Module ProductionModule Production
Production running at 4 locationsCa. 500 modules produced & tested
Production at 7 locationsCommissioning of production sitesStart in October
Barrel Modules Endcap Modules
H.-G. Moser, Max-Planck-Institut für Physik, Munich
16Beauty03, October 2003
EngineeringEngineeringCarbon cylinders for barrel support are ready
Need to be equipped with services
4 of the 18 carbon disks for the endcap module support are producedNeed to be equipped with servicesAgain, high precision/low mass objectsDisk flat to +- 60 m over 2 m!
H.-G. Moser, Max-Planck-Institut für Physik, Munich
17Beauty03, October 2003
TestbeamTestbeam Results Results
H.-G. Moser, Max-Planck-Institut für Physik, Munich
18Beauty03, October 2003
TestbeamTestbeam Results Results
Nominal specifications(after irradiation):
>99% efficiency< 5x10-4 occupancy(readout bandwidth limit)@ 1 fC threshold
Ok for barrel modules
Endcap modules have slightly higher noise.Still possible to meet the specs tuning the threshold
H.-G. Moser, Max-Planck-Institut für Physik, Munich
Temperature sensor on return tube for heater control
Safety temperature sensor on heating element
Heat exchanger
Heating structures
Hea
ter
Filter
Warm monophase
Evaporative systemUsing C3F8 (–30°)
H.-G. Moser, Max-Planck-Institut für Physik, Munich
24Beauty03, October 2003
Assembly and integration
Test area Assembly area
Controlroom
A dedicated facility for ID assembly and integration is set up close to the ATLAS pit.Assembly of SCT barrel, tests of SCT endcaps, TRT assemblySCT/TRT integration and testingPixel Detector assembly
H.-G. Moser, Max-Planck-Institut für Physik, Munich
25Beauty03, October 2003
Expected PerformanceExpected Performance
X0
Material in ID changed compared to initial (‚TDR‘) layout (increased, of course)-increased pixel sensor thickness-More realistic engineering and services
Radius of inner pixel layer 4.3cm -> 5cm
Some impact on momentum and impact parameter resolution
BarrelRegion
H.-G. Moser, Max-Planck-Institut für Physik, Munich
26Beauty03, October 2003
Staged ItemsStaged Items
However, because of funding and schedule problems the initial detector will not have:
Middle pixel layer, at R=9 cm,
Middle pixel disks, at z = +/- 58 cm
TRT ‚C‘ wheels, at II > 1.7
xx x
H.-G. Moser, Max-Planck-Institut für Physik, Munich
27Beauty03, October 2003
ConsequencesConsequences
Impact on:
Missing pixel layers
-> worse impact parameter resolution
-> reduced b-tagging performance
Missing TRT C-wheels
-> worse momentum resolution at II > 1.7
H.-G. Moser, Max-Planck-Institut für Physik, Munich
28Beauty03, October 2003
ScheduleScheduleStart assembly in SR building: April 04SCT barrel ready: January 05SCT endcap C ready April 05SCT endcap A ready August 05
TRT barrel ready January 05TRT endcap C ready October 04TRT endcap A ready September 05
ID barrel ready for installation in ATLAS July 05ID endcap C ready for installation November 05ID endcap A ready for installation March 06
Staged items:3rd pixel layer August 06TRT C wheels July 06
H.-G. Moser, Max-Planck-Institut für Physik, Munich
29Beauty03, October 2003
Conclusions
Most of the technical problems are resolved
Production of detector modules and structures has started
Preparations for detector integration started
Main worry is the tight schedule and fighting delays