DOE Rev of Run IIb Sep 24-26, 2002 1 Silicon sensors procurement and quality assurance WBS 1.1.1 Regina Demina Kansas State University Frank Lehner University.

Slides:

Advertisements

Similar presentations

Silicon Technical Specifications Review General Properties Geometrical Specifications Technology Specifications –Mask –Test Structures –Mechanical –Electrical.

Advertisements

ATLAS SCT Endcap Detector Modules Lutz Feld University of Freiburg for the ATLAS SCT Collaboration Vertex m.

IAP-PAI 25/05/20051 CMS Si Rad. Hardness Introduction Damage in Si Neutron tests => Beam => Irrad. Setup.

Silicon Preshower for the CMS: BARC Participation

January 22, Run IIB Silicon workshop Purdue University Bortoletto Daniela, Bolla Gino, Canepa Anadi Hamamatsu testing I-V characteristics up to 1000V.

Belle-II Meeting Nov Nov Thomas Bergauer (HEPHY Vienna) Status of DSSD Sensors.

128 September, 2005 Silicon Sensor for the CMS Tracker The Silicon Sensors for the Inner Tracker of CMS CMS Tracker and it‘s Silicon Strip Sensors Radiation.

For high fluence, good S/N ratio thanks to: Single strip leakage current I leak  95nA at T  -5C Interstrip capacitance  3pF SVX4 chip 10 modules fully.

Test of Pixel Sensors for the CMS experiment Amitava Roy Purdue University.

DPG 2001 Frank Hartmann (IEKP) P-irradiated-oxygenated Non-irradiated-oxygenated Non-irradiated-non-oxygenated P-irradiated-non-oxygenated sensors put.

First Proton Irradiation of CMS Sensors W. de Boer, A. Dierlamm, A. Furgeri, E. Grigoriev, F. Hartmann, F. Hauler, L. Jungermann, Ch. Piasecki.

LHCC referees meeting, 10 October 2005Børge Svane Nielsen, NBI1 Status of the FMD LHCC referees meeting, 10 October 2005 Børge Svane Nielsen Niels Bohr.

November 3-8, 2002D. Bortoletto - Vertex Silicon Sensors for CMS Daniela Bortoletto Purdue University Grad students: Kim Giolo, Amit Roy, Seunghee.

Sensors for CDF RunIIb silicon upgrade LayerR min (cm)1 MeV eq-n cm * * * * * *10.

October 7, 2003 US Silicon Tracker group Sergey Korjenevski University of Rochester 1 Quality Assurance Test Stand University of Rochester oQTC at Rochester,

Embedded Pitch Adapters a high-yield interconnection solution for strip sensors M. Ullán, C. Fleta, X. Fernández-Tejero, V. Benítez CNM (Barcelona)

Sensor overview Ulrich Heintz Brown University, Providence, RI 6/18/2015U. Heintz - Sensor Overview 1.

St Malo, 13 th April 2002Václav Vrba, Institute of Physics, AS CR 1 Václav Vrba Institute of Physics, AS CR, Prague Silicon pad sensors for W-Si ECal.

October 2001General Tracker Meeting IEKP - Universität Karlsruhe (TH) 1 Results on proton irradiation tests in Karlsruhe F. Hartmann IEKP - Universität.

Semiconductor detectors

Charge collection studies on heavily diodes from RD50 multiplication run G. Kramberger, V. Cindro, I. Mandić, M. Mikuž Ϯ, M. Milovanović, M. Zavrtanik.

Institute of Physics ASCR, Prague Strip Sensors R&D for SCT and ITk Marcela Mikeštíková.

8/22/01Marina Artuso - Pixel Sensor Meeting - Aug Sensor R&D at Syracuse University Marina Artuso Chaouki Boulahouache Brian Gantz Paul Gelling.

Sergey Korjenevski KSU The Run IIb Silicon Tracker Workshop, Dec 12-13, out of 23 Status update and Test results for Run2b Si sensors at KSU Sergey.

Silicon pad detectors for LCCAL: characterisation and first results Antonio Bulgheroni University of Milan – Italy on behalf of LCCAL: Official INFN R&D.

Frank Lehner U Zurich Characterization of inner layer sensors DØ Inner Layer Sensor Production Readiness Review FNAL, 8/8/2003 M. Demarteau, R. Demina,

Medipix sensors included in MP wafers 2 To achieve good spatial resolution through efficient charge collection: Produced by Micron Semiconductor on n-in-p.

Sergey Korjenevski KSU DØ Run2b Silicon meeting, Oct 10, Preliminary testing results of Elma and HPK sensors Sergey Korjenevski Kansas State University.

Quality Test of L1 sensors HPK 10 sensors –Tested all, 6 sent to Fermilab – Test structures, HPK 133 L00 CDF ELMA 9 sensors –Tested 6 of 9.

Silicon Inner Layer Sensor PRR, 8 August G. Ginther Update on the D0 Run IIb Silicon Upgrade for the Inner Layer Sensor PRR 8 August 03 George Ginther.

QA Workshop at CERN 3-4 November Hamamatsu silicon detectors for high energy physics experiments Kazuhisa Yamamura*, Shintaro Kamada.

Summary of Si Strip Group QA Preparation & Schedule and Costs Abhay Deshpande Stony Brook University PHENIX VTX Detector Readiness Review Brookhaven National.

Heavy ion irradiation on silicon strip sensors for GLAST S.Yoshida, K.Yamanaka, T.Ohsugi, H.Masuda T.Mizuno, Y.Fukazawa (Hiroshima Univ.) Y.Iwata, T.Murakami.

Thomas Jefferson National Accelerator Facility Page 1 SVT – Review January Sensors for the Silicon Vertex Tracker Amrit Yegneswaran.

Testing Site Qualification Purpose: –Perform detailed scans of the silicon microstrips to make sure they all work. –Check HPK. Candidates for Certification:

1 ATLAS Pixel Sensors Sally Seidel University of New Mexico U.S. ATLAS Pixel Review LBNL, 2 November 2000.

Heavy ion irradiation on silicon strip sensors for GLAST & Radiation hardening of silicon strip sensors S.Yoshida, K.Yamanaka, T.Ohsugi, H.Masuda T.Mizuno,

8 July 1999A. Peisert, N. Zamiatin1 Silicon Detectors Status Anna Peisert, Cern Nikolai Zamiatin, JINR Plan Design R&D results Specifications Status of.

US ATLAS Upgrade Strip Meeting, Hartmut F.-W. Sadrozinski, SCIPP 1 Upgrade Silicon Strip Detectors (SSD) Hartmut F.-W. Sadrozinski SCIPP, UC Santa Cruz.

Thin Silicon R&D for LC applications D. Bortoletto Purdue University Status report Hybrid Pixel Detectors for LC.

1 ATLAS Pixel Sensors Sally Seidel University of New Mexico U.S. ATLAS Pixel Review LBNL, 9 November 2001.

CBM Silicon Tracking System. Microstrip Detector Module Assembly and Test V.M. Pugatch Kiev Institute for Nuclear Research GSI (CBM experiment), Darmstadt.

1 Silicon Testing at KSU Sergey Korjenevski Kansas State University 06/18/2002 (11 slides total)

1 Device Simulations & Hardware Developments for CBM STS Sudeep Chatterji CBM Group GSI Helmholtz Centre for Heavy Ion Research CBM Collaboration Meeting,

Rev of Run IIb, Nov 4-8, 2002, A. Bean 1 Silicon Management  Organization and Management  Schedule  Resources  Conclusions Alice Bean Univ. of Kansas.

18 March 2009 Thomas Bergauer Prototype batch of DSSD from commercial vendors & Proposal for SVD Layout HEPHY Vienna.

p-on-n Strip Detectors: ATLAS & CMS

Dzero RunIIb Sensor PRR, August 8, Marcel Demarteau Slide 1 DØ Inner Layer Sensor Production Readiness Review August 08, 2003 M. Demarteau for the.

- Performance Studies & Production of the LHCb Silicon Tracker Stefan Koestner (University Zurich) on behalf of the Silicon Tracker Collaboration IT -

Run Iib Workshop Dec 12-13, 2002 Silicon sensors procurement and quality assurance WBS Regina Demina Kansas State University.

Central European Consortium R&D of Central European Consortium (CEC) Status & Plans (Sensor Technology) Georg Steinbrück, Hamburg University Aachen DESY.

Phase 2 Production Discussion We would like to review the conclusions reached at Caltech on US involvement in the phase 2 outer tracker This will be presented.

Production Readiness Review of L0/L1 sensors for DØ Run IIb R. Demina, August, 2003 Irradiation studies of L1 sensors for DØ 2b Regina Demina University.

Maria Rita Coluccia Simon Kwan Fermi National Accelerator Laboratory

GLAST LAT ProjectMarch 24, B Tracker Peer Review, WBS GLAST Large Area Telescope: Tracker Subsystem WBS B: Silicon Strip Detector.

Lehman Review April 2000 D. Bortoletto 1 Forward Pixel Sensors Daniela Bortoletto Purdue University US CMS DOE/NSF Review April 12,2000 Progress.

Ideas for Super LHC tracking upgrades 3/11/04 Marc Weber We have been thinking and meeting to discuss SLHC tracking R&D for a while… Agenda  Introduction:

R. Lipton Vertex ‘98 Santorini, Greece The D0 Silicon Microstrip Tracker (D0SMT) Outline  Design  Detector Studies Coupling capacitors Radiation Damage.

A New Inner-Layer Silicon Micro- Strip Detector for D0 Alice Bean for the D0 Collaboration University of Kansas CIPANP Puerto Rico.

Preparation for silicon sensor arrival sensor delivery schedule aggressive expect 130 L2-L5 sensors each in July and August sensor lot/batch will likely.

ADC values Number of hits Silicon detectors1196  6.2 × 6.2 cm  4.2 × 6.2 cm  2.2 × 6.2 cm 2 52 sectors/modules896 ladders~100 r/o channels1.835.

QA Tests Tests for each sensor Tests for each strip Tests for structures Process stability tests Irradiation tests Bonding & Module assembly Si detectors1272.

Panja Luukka. Silicon Beam Telescope (SiBT) Group Since 2007 a collaboration of several CMS institutes has been operating a silicon micro-strip beam telescope.

Design and development of thin double side silicon microstrip sensors for CBM experiment Mikhail Merkin Skobeltsyn Institute of Nuclear Physics Moscow.

Karlsruhe probe equipment and QA proposals/expertise

SuperB SVT Silicon Sensor Requirements

ILC Detector Activities in Korea

GLAST Large Area Telescope:

Vertex Detector Overview Prototypes R&D Plans Summary.

The LHCb VErtex LOcator

Presentation transcript:

DOE Rev of Run IIb Sep 24-26, Silicon sensors procurement and quality assurance WBS Regina Demina Kansas State University Frank Lehner University of Zurich

DOE Rev of Run IIb Sep 24-26, Outline  Silicon sensor for Run IIb  Radiation environment and silicon sensor specs  Procurement strategy  Quality assurance  Irradiation studies and plans  Conclusions

DOE Rev of Run IIb Sep 24-26, Silicon sensors for DØ IIb  Very tight schedule  Simple, robust design u Single sided sensors u 3 sensor types – L0, L1, L2-5  L0, L1 u Inner radii  small sensors, high radiation u Essential for impact parameter resolution  fine pitch, intermediate strip  L2-L5 u Essential for efficient tracking  larger pitch, robust design u Large quantity  uniform design – one sensor type 144 L1 sensors 7.94x2.50 cm 2 29/58 um pitch 144 L0 sensors 7.94x1.55 cm 2 25/50 um strip/readout pitch 1900 L2 sensors 10.0x4.11 cm 2 30/60 um pitch

DOE Rev of Run IIb Sep 24-26, Requirements for silicon sensors  Main challenge for silicon sensors - radiation  Depletion voltage (  )  Leakage current (  )  noise  Doses comparable to LHC – use their R&D  NB: Uncertainty in  estimate– conservative approach 10 years of CMS at inner radius

DOE Rev of Run IIb Sep 24-26, Depletion voltage  fb  Spec L0, L1 V break >700 V T=-10 o C with warm up periods Specification on breakdown voltage derived based on depletion voltage evolution Spec L2-5 V break >350 V Hamburg model

DOE Rev of Run IIb Sep 24-26, Signal to noise ratio Goal: S/N> 10 Possible if T<-10 o C for L0 and L1 T<-5 o C for L2 – L5 Important to test I leak after irradiation on prototype sensors and on test structures during production I leak  cm 2 Noise contributions: Capacitive load: C(pF) Al strip resistance + analogue cables (L0) Shot noise I leak =I 0 +  Ad (  =3E-17A/cm) Thermal noise in R bias

DOE Rev of Run IIb Sep 24-26, Radiation test results  Sensors of L0-type geometry from 4 vendors (ELMA, HPK, ST, Micron) irradiated by 8 GeV proton beam – Fermilab booster area  10Mrad = 1.8 E14 1MeV n/cm 2 = 22 fb -1 at r=1.8cm Micron HPK ELMA ST T=11 o C T=-12 o C I leak =16uA/cm 2 used in S/N calculation All sensors deplete at 300 V Better than 600V used in estimations Based on preliminary irradiation studies we expect our sensors to survive >22 fb -1

DOE Rev of Run IIb Sep 24-26, Silicon sensors (L0, L1) u single sided n+p s robust, simple, # of dead channels <1%  pitch: 25 & 29  m, every 2 nd strip read out s improve single hit resolution u integrated AC coupling and polysilicon bias resistor s both features work well after irradiation u guard ring structure design for necessary radiation resistance: s either multi-guard ring structure s or single guard ring design with peripheral n- well (Hamamatsu development) u overhanging metal on readout strips s significantly reduced risk of HV breakdown ELMA HPK

DOE Rev of Run IIb Sep 24-26, Silicon sensors (L2-5) u wafer: s 6’’-wafer, n-type silicon, crystal orientation s thickness 320  20  m s wafer warp less than 50  m u depletion voltage: full depletion (FDV)<300V u leakage currents: s <100nA/cm2 at FDV and RT s total <16  A at 350V s junction breakdown > 350V u implant width 8  m with 2-3  m Al-overhang on R/O strips u coupling capacitance > 10pF/cm u interstrip capacitance <1.2pF/cm u Polysilicon resistor 0.8  0.3 M  u bad strips: <1%

DOE Rev of Run IIb Sep 24-26, Silicon sensor procurement strategy L0 and L1 sensors critical for radiation  Qualify two vendors – HPK and ELMA prototypes received from ELMA, undergoing tests 2 L1 sensors used in full module prototype Choose vendor after irradiation of L1 ELMA and HPK sensors L2-L5 sensors large sensors, large quantity, more straight forward design  benefit from 6” technology One vendor – HPK Cost and schedule drivers Very conservative design, experienced vendor  low to moderate risk Sensor design is essentially complete (FNAL, U Zurich, Moscow, KSU) Prototypes ordered for all sensor types

DOE Rev of Run IIb Sep 24-26, Silicon sensor quality assurance program (QA)  QA measurements u Key tests s leakage currents, depletion voltage and visual inspections s 100% on all prototypes and L0,L1 production, 10% on L2 production u Sensor subset tests s Leakage current stability over time, AC- and DC-scans, Rpoly s 100% on all prototypes, 10% on all production u Sensor diagnostic tests s detailed evaluation of sensors (e.g. interstrip C, R) s routinely done on small sample and on sensors missing specs to provide detailed feedback to vendor u Mechanical tests (on OGP at FNAL) s sensor thickness, warp and cut dimensions/accuracy u Irradiation tests on small subset of prototypes and test structures.

DOE Rev of Run IIb Sep 24-26, QA sites Probing sites: KSU – setup complete, work on L0 and L1 prototypes underway SUNY at Stony Brook – setup in progress CINVESTAV in Mexico – setup in progress Fermilab – receiving, distributing, equipment exists Two back up sites – U of Zurich and Moscow State  Equipment u Vibration-free table u R61 Alessi probe station u Keithley 237 ammeter/voltage source u HP4284 LCR meter GPIB interface u Dark box (not shown) u Guard box u Lab view based software

DOE Rev of Run IIb Sep 24-26, QA schedule and manpower BOE – experience with Run 2b prototypes, Run 2a and CMS sensors ~1 technician FTE/institution for 3 years, 3 tasks – setup, maintenance, probing Manpower for QA is identified at all sites Source: MRISource: institutional contribution Source: MRI matching

DOE Rev of Run IIb Sep 24-26, Irradiation at KSU JRM Facility: James R Macdonald lab at KSU u 5-15 MeV proton beam u Beam swept by electrostatic deflector for uniform irradiation u can vary intensity to receive up to 1 Mrad/hour Target chamber Goals: u Irradiation of prototype sensors to ensure sound technology and vendor choice u Irradiation of test structures during production to ensure high quality of delivered sensors u Possibly do a joint study of the “CDF” effect

DOE Rev of Run IIb Sep 24-26, Preliminary results from JRM 20fb -1 Non-oxygen V depl =450V Oxygen V depl =200V 4 ELMA L0 prototype sensors – 3 oxygenated, 1 non-oxygenated irradiated to 1.8E14 n/cm 2 Preliminary results from JRM agree with earlier tests. Sensors are expected to last >20fb -1

DOE Rev of Run IIb Sep 24-26, Conclusions  Use simple design, established technology, experienced vendors  Sensor design is essentially complete  Orders placed for all prototypes  First L0 and L1 prototypes received and are tested  Irradiation facility setup is essentially complete  Based on irradiation tests at Fermilab and at KSU sensors are expected to survive >20fb -1 of luminosity  QA procedures are defined, one QA site setup is complete, two others in progress  Manpower for QA and irradiation is estimated using prior experience, personnel is identified  Silicon sensor schedule risk is low to moderate