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3D sensors for tracking detectors: present and future applications C. Gemme (INFN Genova)

3D sensors for tracking detectors: present and future applications C. Gemme (INFN Genova) Vertex 2013, Lake Starnberg, Germany, 16-20 September 2013 Outline: 3D tracking detectors A real case: IBL AFP CMS . 3D detectors for tracking detectors.

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3D sensors for tracking detectors: present and future applications C. Gemme (INFN Genova)

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  1. 3D sensors for tracking detectors: present and future applications C. Gemme (INFN Genova) Vertex 2013, Lake Starnberg, Germany, 16-20 September 2013 Outline: • 3D tracking detectors • A real case: IBL • AFP • CMS

  2. 3D detectors for tracking detectors • 3D technology is very attractive for future tracking detectors. • Intrinsically radiation hard and able to sustain large fluences • Low depletion voltage and power consumption • Good resolution and time response • Fabrication process is complex, bringing to low yield and high cost. • In this talk I want to review the current status of the possibility to built a full-scale detector for future tracking system. • Experience of IBL • Close Future and perspectives C. Gemme- 3D Tracking detectors

  3. IBL: 3D- oriented Overview • The IBL (Insertable B-Layer) is the first upgrade of the ATLAS Pixel detector and it is going to be installed in LS1. • See Fabian Huegging’s talk for details. • Sensors (planar and 3D) matched to new rad-hard FE-I4 electronics. • First “large” scale 3D tracking system, composed of eight 3D modules at high eta on 14 staves surrounding the beam pipe at ~ 3 cm from the interaction point. Each 3D sensor matches a FEI4 read-out chip, 2x2 cm2 size. • Overall 112 3D modules on detectors. C. Gemme- 3D Tracking detectors

  4. IBL: CNM and FBK Sensors • Two vendors: CNM and FBK • 230um thick 3D n in p-type sensors. • Rad-hard to 5 1015neq/cm2NIEL CNM FBK

  5. Requirements • Main requirements: • Slim-edge:Dead region in z < 225 um JINST 7 (2012) P11010 Fully Irradiated 3D CNM C. Gemme- 3D Tracking detectors

  6. Requirements • Inefficiency at columns (not sensitive areas) • Overall efficiency 97.5% (99%) at 00 (150) • 150 corresponds to IBL tilt angle. • Main requirements: • Slim-edge: Dead region in z < 225 um • End of lifetime Efficiency >97% JINST 7 (2012) P11010 Fully Irradiated 3D CNM C. Gemme- 3D Tracking detectors

  7. Requirements • Main requirements: • Slim-edge: Dead region in z < 225 um • End of lifetime Efficiency >97% • End of lifetime Depletion voltage lower than 200 V and good charge collection. JINST 7 (2012) P11010 Fully Irradiated 3D FBK C. Gemme- 3D Tracking detectors

  8. IBL: Summary of Production 3D • Preliminary as the Module production is still ongoing and will be completed in ~ one month. • Wafers are selected for UBM if at least 3 tiles out of 8 are good • A tile is good if Vbk >25 V C. Gemme- 3D Tracking detectors

  9. Modules Qualification • Modules are assembled in Genova and Bonn: • Gluing of a flex hybrid • Wirebonding • Assembly test at 15°C  ASSY • Burn in: • at least 10x (-40°C,+40°C) • Final Qualification at -10°C  FLEX • Qualification and Ranking C. Gemme- 3D Tracking detectors

  10. Breakdown voltage studies - I • In the first batches, we have verified that CNM has low yield (~65%) after assembly due to Vbk < 25 V or high leakage current. FBK CNM C. Gemme- 3D Tracking detectors

  11. Breakdown voltage studies - I • In the first batches, we have verified that CNM has low yield (~65%) after assembly due to Vbk < 25 V or high leakage current. • The main reason is in the wafer measurement done by CNM to select the good tiles that is limited to the guard ring: • Based on preproduction, expected 10-20% bad at the device level. CNM FBK CNM Temporary column short Guard Ring FBK C. Gemme- 3D Tracking detectors

  12. Breakdown voltage studies - II • Since then, added a IV test after IZM delivery and assembled only the good ones at module level. • CNM sensors not flip-chipped yet back to CNM for re-test after UBM Found 50/72 (69%) of good tiles. • Tested also the red tiles and recover many. • Breakdown voltage distribution for the assembled devices results rather different for CNM and FBK. FBK CNM

  13. Noise studies • The electronic noise depends on Vbias, temperature and sensor type. • Typical values are 140e- (FBK) and 120e- (CNM) at -10C, 3ke threshold and Vbias = 20 V. • SE POSSO AGGIUNGO I VALORI MEDI DI NOISE CALDO/FREDDO e LE DISTRIBUZIOni in SPARE • The difference between noise with and without bias is used to identify disconnected bumps. A cut of 20e is very efficient at RT, while at low temperature detects 10% fakes for FBK. Therefore a source scan is used. CNM C. Gemme- 3D Tracking detectors

  14. Geometrical characteristics 241Am scans in self-triggering mode. • In FBK the edge is active and the occupancy in the edge pixels (rows and columns) is larger than for the ‘normal’ pixels. FBK CNM • In CNM the guard ring stops the charge collection at the edges and the occupancy is therefore the same as the internal pixels.

  15. Cross-talk • The test consists in injecting the maximum charge (~50 ke-) in two neighbouring pixels and measure if any hit is observed. The test is run routinely at 3 ke- threshold and usually the cross-talk is lower than ~3%. • Some crosstalk has been observed in few CNM devices. • Not relevant for data-taking performance. 50 x 250 mm2 Injection Read-out Injection Crosstalk pixels vs inj. charge Occupancy map C. Gemme- 3D Tracking detectors

  16. 3D yields • Bump bonding problems in the first batches. • Then failure rate at the assembly stage is ~28% (FBK) and ~39% (CNM). CNM FBK C. Gemme- 3D Tracking detectors

  17. AFP • ATLAS intends to install a Forward Physics detector (AFP) in order to identify diffracted protons at ≈210 m from the interaction point in 2018. • AFP combines a high resolution pixel tracking detector with a timing detector for the removal of pile-up protons. • The tracking detector will consist of an array of six pixel sensors placed at 2–3 mm from the LHC proton beam. The proximity to the beam is essential for the AFP physics program as it directly increases the sensitivity of the experiment. • Two critical requirements for the Pixel detector: • The device has to cope with a very inhomogeneous radiation distribution from ~5 10 15 1 Mev neutrons to several orders of magnitude less. • The active area of the detector has to be as close as possible to the LHC beam, which means that the dead region of the sensor has to be minimized. C. Gemme- 3D Tracking detectors

  18. AFP: Inhomogeneous radiation • Non-uniform irradiation of CNM 3D IBL devices done in IRRAD1 at CERN-PS. • Good leakage after non-uniform irradiation. • Non uniformly irradiated device performance evaluated at CERN ATLAS 120 GeV pion test-beam. • Efficiency: 98.0% (irradiated side) by masking out dead and noisy pixel cells (due to front-end issues). http://dx.doi.org/10.1016/j.nima.2013.03.064 Efficiency folded into a 2 by 2 pixel area (b) e = 98.9% Threshold: 1700 e- Bias voltage: 130 V Temperature: -20 C (a) e= 92.7% C. Gemme- 3D Tracking detectors

  19. AFP: Slim edge Tight dicing in the bias-tab side • 4 devices (2 CNM and 2 FBK) with ~100 um slim edge tested • AFP_FBK_S1_R9 efficiency ~ 98.3% • Need to do edge efficiency analysis. 100 um 100 um AFP_CNM_S3_R5 e ~ 98.3% CNM FBK e = 98.9% C. Gemme- 3D Tracking detectors

  20. CMS- I • Several devices assembled using with the existing CMS pixel readout chip (ROC) type PSI46v2, which has an array of 80 rows x 52 columns of 100 um x 150 um readout pixels or PSI46dig Inter-electrode distance: 90 μm (1E), 62.5 μm (2E), 45 μm (4E) C. Gemme- 3D Tracking detectors

  21. CMS-II C. Gemme- 3D Tracking detectors

  22. CMS-III C. Gemme- 3D Tracking detectors

  23. Conclusions C. Gemme- 3D Tracking detectors

  24. Noise distribution C. Gemme- 3D Tracking detectors

  25. Charge collection in 3D C. Gemme- 3D Tracking detectors

  26. Xtalk vs Bias: 2ke threshold

  27. Xtalk vs Threshold 1ke VCAL = 900 1.5ke 2ke 3ke 4ke

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