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For the RD42 Collaboration

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1 For the RD42 Collaboration
Status of the R&Ds on Diamond Particle Detectors Mara Bruzzi University of Florence - INFN Firenze For the RD42 Collaboration November 6, VERTEX2002 Outline of the Talk: Introduction 2001/2002 Milestones Status of PolyCrystalline Diamond Particle Detectors Single Crystal Diamond Particle Detectors Summary and RD42 Plans M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

2 The RD42 Collaboration http://rd42.web.cern.ch/RD42/
M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

3 Introduction Diamond Properties:
LHC L ~ 1034 cm-2s-1 in 10 years: f ~ 1015 n/cm2 for pixels SLHC L ~ 1035 cm-2s-1 fast hadron f up to 1016 cm-2  Inner tracking layers must survive  provide high precision tracking to tag b, t, Higgs Diamond Properties: Radiation hardness Low Dielectric Constant  Low Capacitance Low Leakage Current  Low readout noise Room Temperature Operation , Fast signal collection time M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

4 Priorities of Research in 2001/2002
2001/2002 Milestones Priorities of Research in 2001/2002 Increase charge collection distance in a dedicated program with industry to > 250mm Test the Tracking and radiation tolerance properties of the newest diamonds Establish the performance of pixel detectors with radiation hard front-end chips from ATLAS and CMS Establish the performance of large detectors Test diamond trackers with LHC specific electronics (SCTA128 chip ) Irradiate modules sensors and front-end chips together Finalize the geometry and metalization of diamond LHC pixel detectors M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

5 Status of PolyCrystalline Diamond Detectors
Chemical Vapour Deposition - DeBeers Wafer diameter 5-6 inch Metalization Cr/Au, Ti/Au, Ti/W  new 1V/mm Operation, Drift velocity saturated Test procedure: dot  strip  pixel M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

6 R&D with DeBeers Ind. Diamond
Latest Polycrystalline Diamonds Measured with a 90Sr Source System Gain = 124 e/mV QMP = 60mV = 7400e Mean Charge = 76mV = 9400e Source data well separated from 0 Collection distance now 270mm Most Probable Charge now 8000e 99% of PH distribution now above 3000e FWHM/MP ~  Si has ~ 0.5 This is diamond is available in large size The research program worked! M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

7 History of ccd progress
Now M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

8 Material Properties of PolyCrystalline Diamond
Grain-boundaries, dislocations, native defects in Polycrystalline Diamond: limits carrier lifetime, mobility and charge collection distance give rise to polarization and pumping effects affect the radiation hardness ( spatial resolution improves, leakage current decrease, mean signal decreases ) Grain size: ~10-100mm Growth side of PolyDiamond produced by the Florence group State-of-art DeBeers PolyDiamond growth side after lapping M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

9 Basic Research on Defects in PolyCrystalline Diamond
Low quality High quality Thermally Stimulated Currents Analysis: TSC Vrev t T ITSC Native defects at grain boundaries: Main + RT tail Et ~1eV, s ~ cm2, Nt ~ cm-3 M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

10 Optimising CCE through Material Removal
Columnar growth in PolyDiamond films Single-Crystal Line Picture from sample made in Florence Removal from growth () and substrate () Higher grain-boundary density on substrate M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

11 Recent Tracking Studies - CERN Test beam setup
100 GeV/c pion/muon beam 7 planes of CVD diamond strip sensors each 2cmx2cm 50mm pitch, no intermediate strips new metalization procedure 2 additional diamond strip sensors for test several silicon sensors for cross checks strip electronics ( 2ms ): ENC ~100e + 14 e/pF M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

12 Results .. Work in progress Recent Tracking Studies
Uniform signals on all strips Pedestal separated from “0” on all strips 99% of entries above 2000e Mean signal charge ~8640e MP signal charge ~6500e .. Work in progress Module with fully radiation hard SCTA128 electronics Tested with Sr90  ready for beam test and irradiation Charge distribution clearly separated from the noise S/N 8/1 efficiency will be measured in test beams at 40MHz clock rate Improve position resolution by measuring charge sharing between strips M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

13 Dark Current decreases with fluence S/N decreases at 2x1015cm-2
Radiation Hardness Signal to Noise Resolution Dark Current decreases with fluence S/N decreases at 2x1015cm-2 Resolution improves at 2x1015 cm-2 M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

14 Other Radiation Effects
Pumping and Trapping f = 5x1014 n/cm2 Pumping effect less evident Defects at Et ~1eV partially removed or compensated f = 2.0x1015 n/cm2 M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

15 Single Crystal CVD Diamond Particle Detectors
Single Crystal films produced by DeBeers: Microwave plasma-assisted CVD Homoepitaxial diamond films grown from HPHT synthetic diamond substrates. Samples size: mm thick, 6mm diameter Carrier RT mn ~ 4500 cm2/Vs mh ~ 3800 cm2/Vs ~ factor 2 higher than for natural single-crystal diamond Carrier lifetime: exceeds 2ms Dramatic improvement as compared with natural and polycrystalline CVD diamond (~ few ns) Dislocation less than 106 cm-2 Nitrogen content of the order of 1015cm-3 M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

16 Performance of Single Crystal Diamond Detector
New metalization ( Al, no carbide involved ) M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

17 Single Crystal CVD Diamond Detector: CCE
Charge Collection Distance ~ Device Thickness ( over 90-95%)  ~ 100% Charge Collection Efficiency M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

18 Single Crystal CVD Diamond Detector: Pumping
Stable Signal, with no evidence of priming/polarization effects!  Single Crystal Diamonds do not pump like polycrystalline material. M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

19 Polycrystalline Diamond I
Summary Polycrystalline Diamond I Charge collection 270mm collection distance MP signal 8000 e 99% of charge distribution above 3000e FWHM/MP  0.95 Tracking Results Operated a 7 plane telescope with 50mm pitch detectors high efficiency and tracking precision of 10-20mm Rad-hard SCTA128 electronics (DMILL ) built Source tests indicate high efficiency at 40MHz Beam test and irradiation this year Radiation Hardness dark current decreases with fluence some loss of S/N with fluence Resolution improves with fluence M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

20 Polycrystalline Diamond II Single Crystal Diamond: Future ?
Summary Polycrystalline Diamond II Diamond Pixel Detectors Successfully tested ATLAS and CMS pixels patterns Bump-bonding yield  100% Excellent correlation between telescope and pixel data Reasonable spatial resolution attained Radiation hard chips just arrived Single Crystal Diamond: Future ? Material Characteristics mn ~ 4500 cm2/Vs , mh ~ 3800 cm2/Vs Carrier lifetime exceeds 2ms low native defect content Detector performance no pumping effect 100% charge collection efficiency over 550mm M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

21 collection distance  300mm improved uniformity
Future Plans of RD42 Charge Collection collection distance  300mm improved uniformity correlation between defects and detector performance Radiation hardness of diamond trackers and pixel detectors Irradiation with p, p, n up to 5x1015cm-2 Beam tests with Diamond Trackers and Pixel detectors Trackers with SCTA Electronics Pixel detectors with ATLAS and CMS and rad hard elect. Construct the full ATLAS diamond pixel module M.Bruzzi for RD42 Coll.- Status of R&D on Diamond Particle Detectors- Vertex2002, Hawaii, Nov.4-8, 2002

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