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GridPix – chip post processing

GridPix – chip post processing. Jurriaan Schmitz. About Jurriaan Schmitz. Ph.D. experimental physics 1994 Universiteit van Amsterdam/NIKHEF. Senior Scientist at Philips Research 1994-2002. Full professor at University of Twente 2002-present. Outline. The concept of wafer post-processing

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GridPix – chip post processing

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  1. GridPix – chip post processing Jurriaan Schmitz Jurriaan Schmitz - chip post-processing

  2. About Jurriaan Schmitz Ph.D. experimental physics 1994 Universiteit van Amsterdam/NIKHEF Senior Scientist at Philips Research1994-2002 Full professor at University of Twente2002-present Jurriaan Schmitz - chip post-processing

  3. Outline • The concept of wafer post-processing • Successes of wafer post-processing • Recent results • Perspective for radiation imaging Jurriaan Schmitz - chip post-processing

  4. The More than Moore domain of microtechnology “Moore’s Law” (but not exactly) Feature size Year of first mass production Jurriaan Schmitz - chip post-processing

  5. Industry & academia Industry Industry & academia The More than Moore domain of microtechnology Source: ENIAC Jurriaan Schmitz - chip post-processing

  6. Traditional IC: Computing Data Storage Electrical Communication Possible extensions: High quality passives Wireless communication Optical communication Sensing and Actuating More than Moore: new functions What’s 20*2.1? Forty-two Jurriaan Schmitz - chip post-processing

  7. The fabrication challenge How to combine electronics with sensors, actuators, optical components, …? • Hybrid (solder/bump the components together) • 3-D integration by die stacking (e.g. 3D MAPS) • Pre-CMOS: Make component, then make CMOS on the same wafer • Intermediate: Mix the component and CMOS processes • … or post-CMOS: add components on top of a finished CMOS chip Majority @ Vertex ’09 Jurriaan Schmitz - chip post-processing

  8. MEMS-first monolithic integration:Sandia 3-D accelerometer Jurriaan Schmitz - chip post-processing

  9. Intermediate processing:mix the MEMS and CMOS fabrication NIST gas sensor Twente: Kovalgin, J. Electrochem. Soc. 153 (9) H181 Jurriaan Schmitz - chip post-processing

  10. Wafer post-processing a. Chip fabrication b. Wafer dicing Jurriaan Schmitz - chip post-processing

  11. Wafer post-processing a. Chip fabrication b. Post-processing c. Wafer dicing Jurriaan Schmitz - chip post-processing

  12. Chip fabrication: standard, at any regular (CMOS) fab Post-processing: special,in a custom CR laboratory Wafer dicing, packaging: specialized work like MEMS packaging, e.g. Amkor, Boschman a. Chip fabrication b. Post-processing c. Wafer dicing Logistics Jurriaan Schmitz - chip post-processing

  13. We do not interfere with the (CMOS) fab process We can buy good quality chips We can use any lab for this Excellent alignment and contacts Cheap mass-manufacturing We must keep the CMOS intact We have to think the final stages through very carefully! (Standard solutions may fail) a. Chip fabrication b. Post-processing c. Wafer dicing Pros and cons Jurriaan Schmitz - chip post-processing

  14. Outline • The concept of wafer post-processing • Successes of wafer post-processing • Active pixel sensors • LCoS • Digital MicroMirrors • Recent results • Perspective for radiation imaging Jurriaan Schmitz - chip post-processing

  15. Wafer post-processing example: CMOS image sensor (see “MAPS”) Jurriaan Schmitz - chip post-processing

  16. Wafer post-processing example: Liquid-Crystal-on-Silicon Cover glass Electrode Liquid crystal Reflector CMOS Jurriaan Schmitz - chip post-processing

  17. Wafer post-processing example: Digital MicroMirror™ Jurriaan Schmitz - chip post-processing

  18. Jurriaan Schmitz - chip post-processing

  19. Outline • The concept of wafer post-processing • Successes of wafer post-processing • Recent results • Micromechanical structures • Photodetectors • 3D electronics • Perspective for radiation imaging Jurriaan Schmitz - chip post-processing

  20. UC Berkeley: SiGe Resonator on top of CMOS Jurriaan Schmitz - chip post-processing

  21. Example: silicon photodiodes on top of CMOSCEA-LETI, IEDM 2006 Jurriaan Schmitz - chip post-processing

  22. Rohm corp.: CIGS image sensor on CMOSIEDM 2008 Jurriaan Schmitz - chip post-processing

  23. CMOS on top of CMOS! (3D integration) B. Rajendran et al., IEEE Trans. El. Dev. 54 (4) 707 A. W. Topol et al., IBM J. Res. & Dev. 50 (4/5) 491 I. Brunets et al., IEEE Trans. El. Dev. 56 (8) 1637 Jurriaan Schmitz - chip post-processing

  24. CMOS post-processing: game rules Careful treatment of the underlying CMOS: • Temperature ≤ 450 °C • Mild (or no) plasmas • Maintain the H balance in the MOSFET • Limited mechanical stress The CMOS properties must remain unchanged:only then the standard infrastructure can be used. Further reading: Jurriaan Schmitz, Nucl. Instr. Meth. A 576 (2007) 142. Jurriaan Schmitz - chip post-processing

  25. Outline • The concept of wafer post-processing • Successes of wafer post-processing • Recent results • Perspective for radiation imaging • MPGD: InGrid/GridPix • Future Jurriaan Schmitz - chip post-processing

  26. Bottleneck issues in radiation imaging Power mgt. (cooling) Yield of interconnects (E/O) System mass (rad. lengths) What’s the answer? Jurriaan Schmitz - chip post-processing

  27. Bottleneck issues in electronics Power mgt. (cooling) Yield of interconnects System mass Solution in electronics:Integration and miniaturization Jurriaan Schmitz - chip post-processing

  28. Radiation imaging – gaseous detectors Traditional MWPC InGrid Particle Cathodeplanes Anodewires Jurriaan Schmitz - chip post-processing

  29. InGrid: Integrated Grid • Use an ASIC as read-out electronics • Perfect alignment holes to pixels • No dead areas • Geometrical freedom • No manual manufacturing Cathode Grid Supporting pillar Pixel pad CMOS chip Jurriaan Schmitz - chip post-processing

  30. The microsystem Al membrane (-400-450 V) SU-8 pillar (50 μm high) a-Si protection Medipix2 chip (or Timepix) Jurriaan Schmitz - chip post-processing

  31. Deposit spark protection film:a-Si or Silicon-rich nitride SU-8 photoresist for pillars Al deposition is critical:unexposed SU-8 (yellow) should not crosslink Al patterning also critical: lithography at room temperature to protect SU-8 Membrane release at end, after wafer dicing (fragility) Process flow – suspended membrane Spark protection 50 µm SU-8 coating and exposure 0.8 µm Al deposition + patterning SU-8 development Jurriaan Schmitz - chip post-processing

  32. The InGrid detector • 2-D and 3-D mip-tracking shown • Good energy resolution (11.7% FWHM for 55Fe in Ar/CH4) • Micromegas built on a chip, as well as GEM • Multiple electrodes shown • Beam tests for mip-tracking and transition radiation Jurriaan Schmitz - chip post-processing

  33. The next step: other radiation imagers • Semiconductors on a chip • Amorphous silicon: shown (e.g. Wyrsch et al.) • Polycrystalline silicon: first steps made • CIGS: rad-hard!! • Integrate components for optical communication? • Scintillator on an APS? MCP on a chip? Vallerga et al. Melai et al. SigmaDigitalXray Jurriaan Schmitz - chip post-processing

  34. Conclusions What can we build on top of CMOS? • Light projectors • CMOS imagers • More electronics • Radiation imaging detectors • … There’s plenty of room at the top! Jurriaan Schmitz - chip post-processing

  35. Thanks… My low-temperature coworkers: • Tom Aarnink, Victor Blanco Carballo, Arjen Boogaard, Ihor Brunets, Jisk Holleman, Alexey Kovalgin, Jiwu Lu, Joost Melai, Cora Salm, Sander Smits, Rob Wolters, Yevgen Bilevych, Marten Bosma, Max Chefdeville, Harry van der Graaf, Martin Fransen, Jan Visschers, Jan Timmermans Our sponsors: • The Dutch Technology Foundation, FOM • NXP Research, Adixen/Alcatel, ASM International …and the Medipix consortium Jurriaan Schmitz - chip post-processing

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